Name
java - launch a Java application
Synopsis
To launch a class file:
java
[options] mainclass
[args ...]
To launch the main class in a JAR file:
java
[options] -jar
jarfile [args ...]
To launch the main class in a module:
java
[options] -m
module[/
mainclass] [args
...]
or
java
[options] --module
module[/
mainclass] [args
...]
To launch a source-file program:
java
[options] source-file
[args ...]
- options
- Optional: Specifies command-line options separated by spaces. See Overview of Java Options for a description of available options.
- mainclass
-
Specifies the name of the class to be launched. Command-line entries
following
classname
are the arguments for the main method. -jar
jarfile-
Executes a program encapsulated in a JAR file. The jarfile
argument is the name of a JAR file with a manifest that contains a line
in the form
Main-Class:
classname that defines the class with thepublic static void main(String[] args)
method that serves as your application's starting point. When you use-jar
, the specified JAR file is the source of all user classes, and other class path settings are ignored. If you're using JAR files, then see jar. -m
or--module
module[/
mainclass]-
Executes the main class in a module specified by mainclass if it is given, or, if it is not given, the value in the module. In other words, mainclass can be used when it is not specified by the module, or to override the value when it is specified.
- source-file
- Only used to launch a source-file program. Specifies the source file that contains the main class when using source-file mode. See Using Source-File Mode to Launch Source-Code Programs
- args ...
-
Optional: Arguments following mainclass, source-file,
-jar
jarfile, and-m
or--module
module/
mainclass are passed as arguments to the main class.
Description
The java
command starts a Java application. It does this
by starting the Java Virtual Machine (JVM), loading the specified class,
and calling that class's main()
method. The method must be
declared public
and static
, it must not return
any value, and it must accept a String
array as a
parameter. The method declaration has the following form:
public static void main(String[] args)
In source-file mode, the java
command can launch a class
declared in a source file. See Using
Source-File Mode to Launch Source-Code Programs for a description of
using the source-file mode.
Note: You can use the
JDK_JAVA_OPTIONS
launcher environment variable to prepend its content to the actual command line of thejava
launcher. See Using the JDK_JAVA_OPTIONS Launcher Environment Variable.
By default, the first argument that isn't an option of the
java
command is the fully qualified name of the class to be
called. If -jar
is specified, then its argument is the name
of the JAR file containing class and resource files for the application.
The startup class must be indicated by the Main-Class
manifest header in its manifest file.
Arguments after the class file name or the JAR file name are passed
to the main()
method.
javaw
Windows: The javaw
command is identical
to java
, except that with javaw
there's no
associated console window. Use javaw
when you don't want a
command prompt window to appear. The javaw
launcher will,
however, display a dialog box with error information if a launch
fails.
Using Source-File Mode to Launch Source-Code Programs
To launch a class declared in a source file, run the
java
launcher in source-file mode. Entering source-file
mode is determined by two items on the java
command
line:
The first item on the command line that is not an option or part of an option. In other words, the item in the command line that would otherwise be the main class name.
The
--source
version option, if present.
If the class identifies an existing file that has a
.java
extension, or if the --source
option is
specified, then source-file mode is selected. The source file is then
compiled and run. The --source
option can be used to
specify the source version or N of the source code.
This determines the API that can be used. When you set
--source
N, you can only use the public API that
was defined in JDK N.
Note: The valid values of N change for each release, with new values added and old values removed. You'll get an error message if you use a value of N that is no longer supported. The supported values of N are the current Java SE release (
25
) and a limited number of previous releases, detailed in the command-line help forjavac
, under the--source
and--release
options.
If the file does not have the .java
extension, the
--source
option must be used to tell the java
command to use the source-file mode. The --source
option is
used for cases when the source file is a "script" to be executed and the
name of the source file does not follow the normal naming conventions
for Java source files.
In source-file mode, the effect is as though the source file is compiled into memory, and the first class found in the source file is executed. Any arguments placed after the name of the source file in the original command line are passed to the compiled class when it is executed.
For example, if a file were named HelloWorld.java
and
contained a class named HelloWorld
, then the source-file
mode command to launch the class would be:
java HelloWorld.java
This use of source-file mode is informally equivalent to using the following two commands:
javac -d <memory> --source-path <source-root> HelloWorld.java
java --class-path <memory> HelloWorld
where <source-root>
is computed
In source-file mode, any additional command-line options are processed as follows:
The launcher scans the options specified before the source file for any that are relevant in order to compile the source file.
This includes:
--class-path
,--module-path
,--add-exports
,--add-modules
,--limit-modules
,--patch-module
,--upgrade-module-path
, and any variant forms of those options. It also includes the new--enable-preview
option, described in JEP 12.No provision is made to pass any additional options to the compiler, such as
-processor
or-Werror
.Command-line argument files (
@
-files) may be used in the standard way. Long lists of arguments for either the VM or the program being invoked may be placed in files specified on the command-line by prefixing the filename with an@
character.
In source-file mode, compilation proceeds as follows:
Any command-line options that are relevant to the compilation environment are taken into account. These include:
--class-path
/-classpath
/-cp
,--module-path
/-p
,--add-exports
,--add-modules
,--limit-modules
,--patch-module
,--upgrade-module-path
,--enable-preview
.The root of the source tree,
<source-root>
is computed from the package of the class being launched. For example, ifHelloWorld.java
declared its classes to be in thehello
package, then the fileHelloWorld.java
is expected to reside in the directorysomedir/hello/
. In this case,somedir
is computed to be the root of the source tree.The root of the source tree serves as the source-path for compilation, so that other source files found in that tree and are needed by
HelloWorld
could be compiled.Annotation processing is disabled, as if
-proc:none
is in effect.If a version is specified, via the
--source
option, the value is used as the argument for an implicit--release
option for the compilation. This sets both the source version accepted by compiler and the system API that may be used by the code in the source file.If
--enable-preview
is specified, the--source N
arguments can be omitted. If the Java runtime version isN
, then--release N
is implied when compiling source files.If a
module-info.java
file exists in the<source-root>
directory, its module declaration is used to define a named module that will contain all the classes compiled from.java
files in the source tree. Ifmodule-info.java
does not exist, all the classes compiled from source files will be compiled in the context of the unnamed module.The source file that is launched should contain one or more top-level classes, the first of which is taken as the class to be executed.
For the source file that is launched, the compiler does not enforce the optional restriction defined at the end of JLS 7.6, that a type in a named package should exist in a file whose name is composed from the type name followed by the
.java
extension.If a source file contains errors, appropriate error messages are written to the standard error stream, and the launcher exits with a non-zero exit code.
In source-file mode, execution proceeds as follows:
The class to be executed is the first top-level class found in the source file. It must contain a declaration of an entry
main
method.The compiled classes are loaded by a custom class loader, that delegates to the application class loader. This implies that classes appearing on the application class path cannot refer to any classes declared in source files.
If a
module-info.java
file exists in the<source-root>
directory, then all the classes compiled from.java
files in the source tree will be in that module, which will serve as the root module for the execution of the program. Ifmodule-info.java
does not exist, the compiled classes are executed in the context of an unnamed module, as though--add-modules=ALL-DEFAULT
is in effect. This is in addition to any other--add-module
options that may be have been specified on the command line.Any arguments appearing after the name of the file on the command line are passed to the main method in the obvious way.
It is an error if there is a class on the application class path whose name is the same as that of the class to be executed.
See JEP 458: Launch Multi-File Source-Code Programs for complete details.
Using the JDK_JAVA_OPTIONS Launcher Environment Variable
JDK_JAVA_OPTIONS
prepends its content to the options
parsed from the command line. The content of the
JDK_JAVA_OPTIONS
environment variable is a list of
arguments separated by white-space characters (as determined by
isspace()
). These are prepended to the command line
arguments passed to java
launcher. The encoding requirement
for the environment variable is the same as the java
command line on the system. JDK_JAVA_OPTIONS
environment
variable content is treated in the same manner as that specified in the
command line.
Single ('
) or double ("
) quotes can be used
to enclose arguments that contain whitespace characters. All content
between the open quote and the first matching close quote are preserved
by simply removing the pair of quotes. In case a matching quote is not
found, the launcher will abort with an error message.
@
-files are supported as they are specified in the command
line. However, as in @
-files, use of a wildcard is not
supported. In order to mitigate potential misuse of
JDK_JAVA_OPTIONS
behavior, options that specify the main
class (such as -jar
) or cause the java
launcher to exit without executing the main class (such as
-h
) are disallowed in the environment variable. If any of
these options appear in the environment variable, the launcher will
abort with an error message. When JDK_JAVA_OPTIONS
is set,
the launcher prints a message to stderr as a reminder.
Example:
$ export JDK_JAVA_OPTIONS='-g @file1 -Dprop=value @file2 -Dws.prop="white spaces"'
$ java -Xint @file3
is equivalent to the command line:
java -g @file1 -Dprop=value @file2 -Dws.prop="white spaces" -Xint @file3
Overview of Java Options
The java
command supports a wide range of options in the
following categories:
Standard Options for Java: Options guaranteed to be supported by all implementations of the Java Virtual Machine (JVM). They're used for common actions, such as checking the version of the JRE, setting the class path, enabling verbose output, and so on.
Extra Options for Java: General purpose options that are specific to the Java HotSpot Virtual Machine. They aren't guaranteed to be supported by all JVM implementations, and are subject to change. These options start with
-X
.
The advanced options aren't recommended for casual use. These are
developer options used for tuning specific areas of the Java HotSpot
Virtual Machine operation that often have specific system requirements
and may require privileged access to system configuration parameters.
Several examples of performance tuning are provided in Performance Tuning Examples.
These options aren't guaranteed to be supported by all JVM
implementations and are subject to change. Advanced options start with
-XX
.
Advanced Runtime Options for Java: Control the runtime behavior of the Java HotSpot VM.
Advanced JIT Compiler Options for java: Control the dynamic just-in-time (JIT) compilation performed by the Java HotSpot VM.
Advanced Serviceability Options for Java: Enable gathering system information and performing extensive debugging.
Advanced Garbage Collection Options for Java: Control how garbage collection (GC) is performed by the Java HotSpot
Boolean options are used to either enable a feature that's disabled
by default or disable a feature that's enabled by default. Such options
don't require a parameter. Boolean -XX
options are enabled
using the plus sign (-XX:+
OptionName) and disabled
using the minus sign (-XX:-
OptionName).
For options that require an argument, the argument may be separated
from the option name by a space, a colon (:), or an equal sign (=), or
the argument may directly follow the option (the exact syntax differs
for each option). If you're expected to specify the size in bytes, then
you can use no suffix, or use the suffix k
or
K
for kilobytes (KB), m
or M
for
megabytes (MB), or g
or G
for gigabytes (GB).
For example, to set the size to 8 GB, you can specify either
8g
, 8192m
, 8388608k
, or
8589934592
as the argument. If you are expected to specify
the percentage, then use a number from 0 to 1. For example, specify
0.25
for 25%.
The following sections describe the options that are deprecated, obsolete, and removed:
Deprecated Java Options: Accepted and acted upon --- a warning is issued when they're used.
Obsolete Java Options: Accepted but ignored --- a warning is issued when they're used.
Removed Java Options: Removed --- using them results in an error.
Standard Options for Java
These are the most commonly used options supported by all implementations of the JVM.
Note: To specify an argument for a long option, you can use either
--
name=
value or--
name value.
-agentlib:
libname[=
options]-
Loads the specified native agent library. After the library name, a comma-separated list of options specific to the library can be used. If the option
-agentlib:foo
is specified, then the JVM attempts to load the library namedfoo
using the platform specific naming conventions and locations:Linux and other POSIX-like platforms: The JVM attempts to load the library named
libfoo.so
in the location specified by theLD_LIBRARY_PATH
system variable.macOS: The JVM attempts to load the library named
libfoo.dylib
in the location specified by theDYLD_LIBRARY_PATH
system variable.Windows: The JVM attempts to load the library named
foo.dll
in the location specified by thePATH
system variable.The following example shows how to load the Java Debug Wire Protocol (JDWP) library and listen for the socket connection on port 8000, suspending the JVM before the main class loads:
-agentlib:jdwp=transport=dt_socket,server=y,address=8000
-agentpath:
pathname[=
options]-
Loads the native agent library specified by the absolute path name. This
option is equivalent to
-agentlib
but uses the full path and file name of the library. --class-path
classpath,-classpath
classpath, or-cp
classpath-
Specifies a list of directories, JAR files, and ZIP archives to search for class files.
On Windows, semicolons (
;
) separate entities in this list; on other platforms it is a colon (:
).Specifying classpath overrides any setting of the
CLASSPATH
environment variable. If the class path option isn't used and classpath isn't set, then the user class path consists of the current directory (.).As a special convenience, a class path element that contains a base name of an asterisk (*) is considered equivalent to specifying a list of all the files in the directory with the extension
.jar
or.JAR
. A Java program can't tell the difference between the two invocations. For example, if the directory mydir containsa.jar
andb.JAR
, then the class path element mydir/* is expanded toA.jar:b.JAR
, except that the order of JAR files is unspecified. All.jar
files in the specified directory, even hidden ones, are included in the list. A class path entry consisting of an asterisk (*) expands to a list of all the jar files in the current directory. TheCLASSPATH
environment variable, where defined, is similarly expanded. Any class path wildcard expansion that occurs before the Java VM is started. Java programs never see wildcards that aren't expanded except by querying the environment, such as by callingSystem.getenv("CLASSPATH")
. --disable-@files
-
Can be used anywhere on the command line, including in an argument file,
to prevent further
@filename
expansion. This option stops expanding@
-argfiles after the option. --enable-preview
- Allows classes to depend on preview features of the release.
--enable-native-access
module[,
module...]-
Native access involves access to code or data outside the Java runtime.
This is generally unsafe and, if done incorrectly, might crash the JVM
or result in memory corruption. Methods that provide native access are
restricted, and by default their use causes warnings. This option allows
code in the specified modules to use restricted methods without
warnings. module can be
ALL-UNNAMED
to indicate code on the class path. When this option is present, any use of restricted methods by code outside the specified modules causes anIllegalCallerException
. --finalization=
value- Controls whether the JVM performs finalization of objects. Valid values are "enabled" and "disabled". Finalization is enabled by default, so the value "enabled" does nothing. The value "disabled" disables finalization, so that no finalizers are invoked.
--module-path
modulepath... or-p
modulepath-
Specifies where to find application modules with a list of path elements. The elements of a module path can be a file path to a module or a directory containing modules. Each module is either a modular JAR or an exploded-module directory.
On Windows, semicolons (
;
) separate path elements in this list; on other platforms it is a colon (:
). --upgrade-module-path
modulepath...-
Specifies where to find module replacements of upgradeable modules in the runtime image with a list of path elements. The elements of a module path can be a file path to a module or a directory containing modules. Each module is either a modular JAR or an exploded-module directory.
On Windows, semicolons (
;
) separate path elements in this list; on other platforms it is a colon (:
). --add-modules
module[,
module...]-
Specifies the root modules to resolve in addition to the initial module.
module can also be
ALL-DEFAULT
,ALL-SYSTEM
, andALL-MODULE-PATH
. --list-modules
- Lists the observable modules and then exits.
-d
module_name or--describe-module
module_name- Describes a specified module and then exits.
--dry-run
-
Creates the VM but doesn't execute the main method. This
--dry-run
option might be useful for validating the command-line options such as the module system configuration. --validate-modules
- Validates all modules and exit. This option is helpful for finding conflicts and other errors with modules on the module path.
-D
property=
value-
Sets a system property value. The property variable is a string
with no spaces that represents the name of the property. The
value variable is a string that represents the value of the
property. If value is a string with spaces, then enclose it in
quotation marks (for example
-Dfoo="foo bar"
). -disableassertions
[:
[packagename]...|:
classname] or-da
[:
[packagename]...|:
classname]-
Disables assertions. By default, assertions are disabled in all packages and classes. With no arguments,
-disableassertions
(-da
) disables assertions in all packages and classes. With the packagename argument ending in...
, the switch disables assertions in the specified package and any subpackages. If the argument is simply...
, then the switch disables assertions in the unnamed package in the current working directory. With the classname argument, the switch disables assertions in the specified class.The
-disableassertions
(-da
) option applies to all class loaders and to system classes (which don't have a class loader). There's one exception to this rule: If the option is provided with no arguments, then it doesn't apply to system classes. This makes it easy to disable assertions in all classes except for system classes. The-disablesystemassertions
option enables you to disable assertions in all system classes. To explicitly enable assertions in specific packages or classes, use the-enableassertions
(-ea
) option. Both options can be used at the same time. For example, to run theMyClass
application with assertions enabled in the packagecom.wombat.fruitbat
(and any subpackages) but disabled in the classcom.wombat.fruitbat.Brickbat
, use the following command:java -ea:com.wombat.fruitbat... -da:com.wombat.fruitbat.Brickbat MyClass
-disablesystemassertions
or-dsa
- Disables assertions in all system classes.
-enableassertions
[:
[packagename]...|:
classname] or-ea
[:
[packagename]...|:
classname]-
Enables assertions. By default, assertions are disabled in all packages and classes. With no arguments,
-enableassertions
(-ea
) enables assertions in all packages and classes. With the packagename argument ending in...
, the switch enables assertions in the specified package and any subpackages. If the argument is simply...
, then the switch enables assertions in the unnamed package in the current working directory. With the classname argument, the switch enables assertions in the specified class.The
-enableassertions
(-ea
) option applies to all class loaders and to system classes (which don't have a class loader). There's one exception to this rule: If the option is provided with no arguments, then it doesn't apply to system classes. This makes it easy to enable assertions in all classes except for system classes. The-enablesystemassertions
option provides a separate switch to enable assertions in all system classes. To explicitly disable assertions in specific packages or classes, use the-disableassertions
(-da
) option. If a single command contains multiple instances of these switches, then they're processed in order, before loading any classes. For example, to run theMyClass
application with assertions enabled only in the packagecom.wombat.fruitbat
(and any subpackages) but disabled in the classcom.wombat.fruitbat.Brickbat
, use the following command:java -ea:com.wombat.fruitbat... -da:com.wombat.fruitbat.Brickbat MyClass
-enablesystemassertions
or-esa
- Enables assertions in all system classes.
-help
,-h
, or-?
- Prints the help message to the error stream.
--help
- Prints the help message to the output stream.
-javaagent:
jarpath[=
options]-
Loads the specified Java programming language agent. See
java.lang.instrument
. --show-version
- Prints the product version to the output stream and continues.
-showversion
- Prints the product version to the error stream and continues.
--show-module-resolution
- Shows module resolution output during startup.
-splash:
imagepath-
Shows the splash screen with the image specified by imagepath. HiDPI scaled images are automatically supported and used if available. The unscaled image file name, such as
image.ext
, should always be passed as the argument to the-splash
option. The most appropriate scaled image provided is picked up automatically.For example, to show the
splash.gif
file from theimages
directory when starting your application, use the following option:-splash:images/splash.gif
See the SplashScreen API documentation for more information.
-verbose:class
- Displays information about each loaded class.
-verbose:gc
- Displays information about each garbage collection (GC) event.
-verbose:jni
- Displays information about the use of native methods and other Java Native Interface (JNI) activity.
-verbose:module
- Displays information about the modules in use.
--version
- Prints product version to the output stream and exits.
-version
- Prints product version to the error stream and exits.
-X
- Prints the help on extra options to the error stream.
--help-extra
- Prints the help on extra options to the output stream.
@
argfile-
Specifies one or more argument files prefixed by
@
used by thejava
command. It isn't uncommon for thejava
command line to be very long because of the.jar
files needed in the classpath. The@
argfile option overcomes command-line length limitations by enabling the launcher to expand the contents of argument files after shell expansion, but before argument processing. Contents in the argument files are expanded because otherwise, they would be specified on the command line until the--disable-@files
option was encountered.The argument files can also contain the main class name and all options. If an argument file contains all of the options required by the
java
command, then the command line could simply be:java @
argfileSee java Command-Line Argument Files for a description and examples of using
@
-argfiles.
Extra Options for Java
The following java
options are general purpose options
that are specific to the Java HotSpot Virtual Machine.
-Xbatch
-
Disables background compilation. By default, the JVM compiles the method
as a background task, running the method in interpreter mode until the
background compilation is finished. The
-Xbatch
flag disables background compilation so that compilation of all methods proceeds as a foreground task until completed. This option is equivalent to-XX:-BackgroundCompilation
. -Xbootclasspath/a:
directories|zip|JAR-files-
Specifies a list of directories, JAR files, and ZIP archives to append to the end of the default bootstrap class path.
On Windows, semicolons (
;
) separate entities in this list; on other platforms it is a colon (:
). -Xcheck:jni
-
Performs additional checks for Java Native Interface (JNI) functions.
The following checks are considered indicative of significant problems with the native code, and the JVM terminates with an irrecoverable error in such cases:
- The thread doing the call is not attached to the JVM.
- The thread doing the call is using the
JNIEnv
belonging to another thread. - A parameter validation check fails:
- A
jfieldID
, orjmethodID
, is detected as being invalid. For example:- Of the wrong type
- Associated with the wrong class
- A parameter of the wrong type is detected.
- An invalid parameter value is detected. For example:
- NULL where not permitted
- An out-of-bounds array index, or frame capacity
- A non-UTF-8 string
- An invalid JNI reference
- An attempt to use a
ReleaseXXX
function on a parameter not produced by the correspondingGetXXX
function
- A
The following checks only result in warnings being printed:
- A JNI call was made without checking for a pending exception from a previous JNI call, and the current call is not safe when an exception may be pending.
- A class descriptor is in decorated format (
Lname;
) when it should not be. - A
NULL
parameter is allowed, but its use is questionable. - Calling other JNI functions in the scope of
Get/ReleasePrimitiveArrayCritical
orGet/ReleaseStringCritical
Expect a performance degradation when this option is used.
-Xcomp
- Testing mode to exercise JIT compilers. This option should not be used in production environments.
-Xdebug
- Does nothing; deprecated for removal in a future release.
-Xdiag
- Shows additional diagnostic messages.
-Xint
- Runs the application in interpreted-only mode. Compilation to native code is disabled, and all bytecode is executed by the interpreter. The performance benefits offered by the just-in-time (JIT) compiler aren't present in this mode.
-Xinternalversion
-
Displays more detailed JVM version information than the
-version
option, and then exits. -Xlog:
option- Configure or enable logging with the Java Virtual Machine (JVM) unified logging framework. See Enable Logging with the JVM Unified Logging Framework.
-Xmixed
-
Executes all bytecode by the interpreter except for hot methods, which
are compiled to native code. On by default. Use
-Xint
to switch off. -Xmn
size-
Sets the initial and maximum size (in bytes) of the heap for the young generation (nursery) in the generational collectors. Append the letter
k
orK
to indicate kilobytes,m
orM
to indicate megabytes, org
orG
to indicate gigabytes. The young generation region of the heap is used for new objects. GC is performed in this region more often than in other regions. If the size for the young generation is too small, then a lot of minor garbage collections are performed. If the size is too large, then only full garbage collections are performed, which can take a long time to complete. It is recommended that you do not set the size for the young generation for the G1 collector, and keep the size for the young generation greater than 25% and less than 50% of the overall heap size for other collectors. The following examples show how to set the initial and maximum size of young generation to 256 MB using various units:-Xmn256m -Xmn262144k -Xmn268435456
Instead of the
-Xmn
option to set both the initial and maximum size of the heap for the young generation, you can use-XX:NewSize
to set the initial size and-XX:MaxNewSize
to set the maximum size. -Xms
size-
Sets the minimum and the initial size (in bytes) of the heap. This value must be a multiple of 1024 and greater than 1 MB. Append the letter
k
orK
to indicate kilobytes,m
orM
to indicate megabytes, org
orG
to indicate gigabytes. The following examples show how to set the size of allocated memory to 6 MB using various units:-Xms6291456 -Xms6144k -Xms6m
If you do not set this option, then the initial size will be set as the sum of the sizes allocated for the old generation and the young generation. The initial size of the heap for the young generation can be set using the
-Xmn
option or the-XX:NewSize
option.Note that the
-XX:InitialHeapSize
option can also be used to set the initial heap size. If it appears after-Xms
on the command line, then the initial heap size gets set to the value specified with-XX:InitialHeapSize
. -Xmx
size-
Specifies the maximum size (in bytes) of the heap. This value must be a multiple of 1024 and greater than 2 MB. Append the letter
k
orK
to indicate kilobytes,m
orM
to indicate megabytes, org
orG
to indicate gigabytes. The default value is chosen at runtime based on system configuration. For server deployments,-Xms
and-Xmx
are often set to the same value. The following examples show how to set the maximum allowed size of allocated memory to 80 MB using various units:-Xmx83886080 -Xmx81920k -Xmx80m
The
-Xmx
option is equivalent to-XX:MaxHeapSize
. -Xnoclassgc
-
Disables garbage collection (GC) of classes. This can save some GC time,
which shortens interruptions during the application run. When you
specify
-Xnoclassgc
at startup, the class objects in the application are left untouched during GC and are always be considered live. This can result in more memory being permanently occupied which, if not used carefully, throws an out-of-memory exception. -Xrs
-
Reduces the use of operating system signals by the JVM. Shutdown hooks enable the orderly shutdown of a Java application by running user cleanup code (such as closing database connections) at shutdown, even if the JVM terminates abruptly.
Non-Windows:
The JVM catches signals to implement shutdown hooks for unexpected termination. The JVM uses
SIGHUP
,SIGINT
, andSIGTERM
to initiate the running of shutdown hooks.Applications embedding the JVM frequently need to trap signals such as
SIGINT
orSIGTERM
, which can lead to interference with the JVM signal handlers. The-Xrs
option is available to address this issue. When-Xrs
is used, the signal masks forSIGINT
,SIGTERM
,SIGHUP
, andSIGQUIT
aren't changed by the JVM, and signal handlers for these signals aren't installed.
Windows:
The JVM watches for console control events to implement shutdown hooks for unexpected termination. Specifically, the JVM registers a console control handler that begins shutdown-hook processing and returns
TRUE
forCTRL_C_EVENT
,CTRL_CLOSE_EVENT
,CTRL_LOGOFF_EVENT
, andCTRL_SHUTDOWN_EVENT
.The JVM uses a similar mechanism to implement the feature of dumping thread stacks for debugging purposes. The JVM uses
CTRL_BREAK_EVENT
to perform thread dumps.If the JVM is run as a service (for example, as a servlet engine for a web server), then it can receive
CTRL_LOGOFF_EVENT
but shouldn't initiate shutdown because the operating system doesn't actually terminate the process. To avoid possible interference such as this, the-Xrs
option can be used. When the-Xrs
option is used, the JVM doesn't install a console control handler, implying that it doesn't watch for or processCTRL_C_EVENT
,CTRL_CLOSE_EVENT
,CTRL_LOGOFF_EVENT
, orCTRL_SHUTDOWN_EVENT
.
There are two consequences of specifying
-Xrs
:Non-Windows:
SIGQUIT
thread dumps aren't available.Windows: Ctrl + Break thread dumps aren't available.
User code is responsible for causing shutdown hooks to run, for example, by calling
System.exit()
when the JVM is to be terminated. -Xshare:
mode-
Sets the class data sharing (CDS) mode.
Possible mode arguments for this option include the following:
auto
- Use shared class data if possible (default).
on
- Require using shared class data, otherwise fail.
Note: The
-Xshare:on
option is used for testing purposes only. It may cause the VM to unexpectedly exit during start-up when the CDS archive cannot be used (for example, when certain VM parameters are changed, or when a different JDK is used). This option should not be used in production environments.off
- Do not attempt to use shared class data.
-XshowSettings
- Shows all settings and then continues.
-XshowSettings:
category-
Shows settings and continues. Possible category arguments for this option include the following:
all
- Shows all categories of settings in verbose detail.
locale
- Shows settings related to locale.
properties
- Shows settings related to system properties.
security
-
Shows all settings related to security.
sub-category arguments for
security
include the following:security:all
: shows all security settingssecurity:properties
: shows security propertiessecurity:providers
: shows static security provider settingssecurity:tls
: shows TLS related security settings
vm
- Shows the settings of the JVM.
system
- Linux only: Shows host system or container configuration and continues.
-Xss
size-
Sets the thread stack size (in bytes). Append the letter
k
orK
to indicate KB,m
orM
to indicate MB, org
orG
to indicate GB. The actual size may be rounded up to a multiple of the system page size as required by the operating system. The default value depends on the platform. For example:Linux/x64: 1024 KB
Linux/Aarch64: 2048 KB
macOS/x64: 1024 KB
macOS/Aarch64: 2048 KB
Windows: The default value depends on virtual memory
The following examples set the thread stack size to 1024 KB in different units:
-Xss1m -Xss1024k -Xss1048576
This option is similar to
-XX:ThreadStackSize
. --add-reads
module=
target-module(,
target-module)*-
Updates module to read the target-module, regardless
of the module declaration. target-module can be
ALL-UNNAMED
to read all unnamed modules. --add-exports
module/
package=
target-module(,
target-module)*-
Updates module to export package to
target-module, regardless of module declaration.
target-module can be
ALL-UNNAMED
to export to all unnamed modules. --add-opens
module/
package=
target-module(,
target-module)*- Updates module to open package to target-module, regardless of module declaration.
--limit-modules
module[,
module...]- Specifies the limit of the universe of observable modules.
--patch-module
module=
file(;
file)*- Overrides or augments a module with classes and resources in JAR files or directories.
--source
version- Sets the version of the source in source-file mode.
Extra Options for macOS
The following extra options are macOS specific.
-XstartOnFirstThread
-
Runs the
main()
method on the first (AppKit) thread. -Xdock:name=
application_name- Overrides the default application name displayed in dock.
-Xdock:icon=
path_to_icon_file- Overrides the default icon displayed in dock.
Advanced Options for Java
These java
options can be used to enable other advanced
options.
-XX:+UnlockDiagnosticVMOptions
-
Unlocks the options intended for diagnosing the JVM. By default, this option is disabled and diagnostic options aren't available.
Command line options that are enabled with the use of this option are not supported. If you encounter issues while using any of these options, it is very likely that you will be required to reproduce the problem without using any of these unsupported options before Oracle Support can assist with an investigation. It is also possible that any of these options may be removed or their behavior changed without any warning.
-XX:+UnlockExperimentalVMOptions
- Unlocks the options that provide experimental features in the JVM. By default, this option is disabled and experimental features aren't available.
Advanced Runtime Options for Java
These java
options control the runtime behavior of the
Java HotSpot VM.
-XX:ActiveProcessorCount=
x-
Overrides the number of CPUs that the VM will use to calculate the size of thread pools it will use for various operations such as Garbage Collection and ForkJoinPool.
The VM normally determines the number of available processors from the operating system. This flag can be useful for partitioning CPU resources when running multiple Java processes in docker containers. This flag is honored even if
UseContainerSupport
is not enabled. See-XX:-UseContainerSupport
for a description of enabling and disabling container support. -XX:AllocateHeapAt=
path-
Takes a path to the file system and uses memory mapping to allocate the object heap on the memory device. Using this option enables the HotSpot VM to allocate the Java object heap on an alternative memory device, such as an NV-DIMM, specified by the user.
Alternative memory devices that have the same semantics as DRAM, including the semantics of atomic operations, can be used instead of DRAM for the object heap without changing the existing application code. All other memory structures (such as the code heap, metaspace, and thread stacks) continue to reside in DRAM.
Some operating systems expose non-DRAM memory through the file system. Memory-mapped files in these file systems bypass the page cache and provide a direct mapping of virtual memory to the physical memory on the device. The existing heap related flags (such as
-Xmx
and-Xms
) and garbage-collection related flags continue to work as before. -XX:-CompactStrings
-
Disables the Compact Strings feature. By default, this option is enabled. When this option is enabled, Java Strings containing only single-byte characters are internally represented and stored as single-byte-per-character Strings using ISO-8859-1 / Latin-1 encoding. This reduces, by 50%, the amount of space required for Strings containing only single-byte characters. For Java Strings containing at least one multibyte character: these are represented and stored as 2 bytes per character using UTF-16 encoding. Disabling the Compact Strings feature forces the use of UTF-16 encoding as the internal representation for all Java Strings.
Cases where it may be beneficial to disable Compact Strings include the following:
When it's known that an application overwhelmingly will be allocating multibyte character Strings
In the unexpected event where a performance regression is observed in migrating from Java SE 8 to Java SE 9 and an analysis shows that Compact Strings introduces the regression
In both of these scenarios, disabling Compact Strings makes sense.
-XX:ErrorFile=
filename-
Specifies the path and file name to which error data is written when an irrecoverable error occurs. By default, this file is created in the current working directory and named
hs_err_pid
pid.log
where pid is the identifier of the process that encountered the error.The following example shows how to set the default log file (note that the identifier of the process is specified as
%p
):-XX:ErrorFile=./hs_err_pid%p.log
Non-Windows: The following example shows how to set the error log to
/var/log/java/java_error.log
:-XX:ErrorFile=/var/log/java/java_error.log
Windows: The following example shows how to set the error log file to
C:/log/java/java_error.log
:-XX:ErrorFile=C:/log/java/java_error.log
If the file exists, and is writeable, then it will be overwritten. Otherwise, if the file can't be created in the specified directory (due to insufficient space, permission problem, or another issue), then the file is created in the temporary directory for the operating system:
Non-Windows: The temporary directory is
/tmp
.Windows: The temporary directory is specified by the value of the
TMP
environment variable; if that environment variable isn't defined, then the value of theTEMP
environment variable is used.
-XX:+ExtensiveErrorReports
-
Enables the reporting of more extensive error information in the
ErrorFile
. This option can be turned on in environments where maximal information is desired - even if the resulting logs may be quite large and/or contain information that might be considered sensitive. The information can vary from release to release, and across different platforms. By default this option is disabled. -XX:FlightRecorderOptions=
parameter=
value (or)-XX:FlightRecorderOptions:
parameter=
value-
Sets the parameters that control the behavior of JFR. Multiple parameters can be specified by separating them with a comma.
The following list contains the available JFR parameter
=
value entries:globalbuffersize=
size-
Specifies the total amount of primary memory used for data retention.
The default value is based on the value specified for
memorysize
. Change thememorysize
parameter to alter the size of global buffers. maxchunksize=
size-
Specifies the maximum size (in bytes) of the data chunks in a recording.
Append
m
orM
to specify the size in megabytes (MB), org
orG
to specify the size in gigabytes (GB). By default, the maximum size of data chunks is set to 12 MB. The minimum allowed is 1 MB. memorysize=
size-
Determines how much buffer memory should be used, and sets the
globalbuffersize
andnumglobalbuffers
parameters based on the size specified. Appendm
orM
to specify the size in megabytes (MB), org
orG
to specify the size in gigabytes (GB). By default, the memory size is set to 10 MB. numglobalbuffers
-
Specifies the number of global buffers used. The default value is based
on the memory size specified. Change the
memorysize
parameter to alter the number of global buffers. old-object-queue-size=number-of-objects
- Maximum number of old objects to track. By default, the number of objects is set to 256.
preserve-repository=
{true
|false
}- Specifies whether files stored in the disk repository should be kept after the JVM has exited. If false, files are deleted. By default, this parameter is disabled.
repository=
path- Specifies the repository (a directory) for temporary disk storage. By default, the system's temporary directory is used.
retransform=
{true
|false
}- Specifies whether event classes should be retransformed using JVMTI. If false, instrumentation is added when event classes are loaded. By default, this parameter is enabled.
stackdepth=
depth- Stack depth for stack traces. By default, the depth is set to 64 method calls. The maximum is 2048. Values greater than 64 could create significant overhead and reduce performance.
threadbuffersize=
size- Specifies the per-thread local buffer size (in bytes). By default, the local buffer size is set to 8 kilobytes, with a minimum value of 4 kilobytes. Overriding this parameter could reduce performance and is not recommended.
-XX:LargePageSizeInBytes=
size-
Sets the maximum large page size (in bytes) used by the JVM. The size argument must be a valid page size supported by the environment to have any effect. Append the letter
k
orK
to indicate kilobytes,m
orM
to indicate megabytes, org
orG
to indicate gigabytes. By default, the size is set to 0, meaning that the JVM will use the default large page size for the environment as the maximum size for large pages. See Large Pages.The following example describes how to set the large page size to 1 gigabyte (GB):
-XX:LargePageSizeInBytes=1g
-XX:MaxDirectMemorySize=
size-
Sets the maximum total size (in bytes) of the
java.nio
package, direct-buffer allocations. Append the letterk
orK
to indicate kilobytes,m
orM
to indicate megabytes, org
orG
to indicate gigabytes. If not set, the flag is ignored and the JVM chooses the size for NIO direct-buffer allocations automatically.The following examples illustrate how to set the NIO size to 1024 KB in different units:
-XX:MaxDirectMemorySize=1m -XX:MaxDirectMemorySize=1024k -XX:MaxDirectMemorySize=1048576
-XX:-MaxFDLimit
- Disables the attempt to set the soft limit for the number of open file descriptors to the hard limit. By default, this option is enabled on all platforms, but is ignored on Windows. The only time that you may need to disable this is on macOS, where its use imposes a maximum of 10240, which is lower than the actual system maximum.
-XX:NativeMemoryTracking=
mode-
Specifies the mode for tracking JVM native memory usage. Possible mode arguments for this option include the following:
off
-
Instructs not to track JVM native memory usage. This is the default
behavior if you don't specify the
-XX:NativeMemoryTracking
option. summary
- Tracks memory usage only by JVM subsystems, such as Java heap, class, code, and thread.
detail
-
In addition to tracking memory usage by JVM subsystems, track memory
usage by individual
CallSite
, individual virtual memory region and its committed regions.
-XX:TrimNativeHeapInterval=
millis-
Interval, in ms, at which the JVM will trim the native heap. Lower values will reclaim memory more eagerly at the cost of higher overhead. A value of 0 (default) disables native heap trimming. Native heap trimming is performed in a dedicated thread.
This option is only supported on Linux with GNU C Library (glibc).
-XX:+NeverActAsServerClassMachine
-
Enable the "Client VM emulation" mode which only uses the C1 JIT compiler, a 32Mb CodeCache and the Serial GC. The maximum amount of memory that the JVM may use (controlled by the
-XX:MaxRAM=n
flag) is set to 1GB by default. The string "emulated-client" is added to the JVM version string.By default the flag is set to
true
only on Windows in 32-bit mode andfalse
in all other cases.The "Client VM emulation" mode will not be enabled if any of the following flags are used on the command line:
-XX:{+|-}TieredCompilation -XX:CompilationMode=mode -XX:TieredStopAtLevel=n -XX:{+|-}EnableJVMCI -XX:{+|-}UseJVMCICompiler
-XX:ObjectAlignmentInBytes=
alignment-
Sets the memory alignment of Java objects (in bytes). By default, the value is set to 8 bytes. The specified value should be a power of 2, and must be within the range of 8 and 256 (inclusive). This option makes it possible to use compressed pointers with large Java heap sizes.
The heap size limit in bytes is calculated as:
4GB * ObjectAlignmentInBytes
Note: As the alignment value increases, the unused space between objects also increases. As a result, you may not realize any benefits from using compressed pointers with large Java heap sizes.
-XX:OnError=
string-
Sets a custom command or a series of semicolon-separated commands to run when an irrecoverable error occurs. If the string contains spaces, then it must be enclosed in quotation marks.
Non-Windows: The following example shows how the
-XX:OnError
option can be used to run thegcore
command to create a core image, and start thegdb
debugger to attach to the process in case of an irrecoverable error (the%p
designates the current process identifier):-XX:OnError="gcore %p;gdb -p %p"
Windows: The following example shows how the
-XX:OnError
option can be used to run theuserdump.exe
utility to obtain a crash dump in case of an irrecoverable error (the%p
designates the current process identifier). This example assumes that the path to theuserdump.exe
utility is specified in thePATH
environment variable:-XX:OnError="userdump.exe %p"
-XX:OnOutOfMemoryError=
string-
Sets a custom command or a series of semicolon-separated commands to run
when an
OutOfMemoryError
exception is first thrown. If the string contains spaces, then it must be enclosed in quotation marks. For an example of a command string, see the description of the-XX:OnError
option. -XX:+PrintCommandLineFlags
- Enables printing of ergonomically selected JVM flags that appeared on the command line. It can be useful to know the ergonomic values set by the JVM, such as the heap space size and the selected garbage collector. By default, this option is disabled and flags aren't printed.
-XX:+PreserveFramePointer
-
Selects between using the RBP register as a general purpose register
(
-XX:-PreserveFramePointer
) and using the RBP register to hold the frame pointer of the currently executing method (-XX:+PreserveFramePointer
. If the frame pointer is available, then external profiling tools (for example, Linux perf) can construct more accurate stack traces. -XX:+PrintNMTStatistics
-
Enables printing of collected native memory tracking data at JVM exit
when native memory tracking is enabled (see
-XX:NativeMemoryTracking
). By default, this option is disabled and native memory tracking data isn't printed. -XX:SharedArchiveFile=
path-
Specifies the path and name of the class data sharing (CDS) archive file
-XX:+VerifySharedSpaces
- If this option is specified, the JVM will load a CDS archive file only if it passes an integrity check based on CRC32 checksums. The purpose of this flag is to check for unintentional damage to CDS archive files in transmission or storage. To guarantee the security and proper operation of CDS, the user must ensure that the CDS archive files used by Java applications cannot be modified without proper authorization.
-XX:SharedArchiveConfigFile=
shared_config_file- Specifies additional shared data added to the archive file.
-XX:SharedClassListFile=
file_name-
Specifies the text file that contains the names of the classes to store in the class data sharing (CDS) archive. This file contains the full name of one class per line, except slashes (
/
) replace dots (.
). For example, to specify the classesjava.lang.Object
andhello.Main
, create a text file that contains the following two lines:java/lang/Object hello/Main
The classes that you specify in this text file should include the classes that are commonly used by the application. They may include any classes from the application, extension, or bootstrap class paths.
-XX:+ShowCodeDetailsInExceptionMessages
-
Enables printing of improved
NullPointerException
messages. When an application throws aNullPointerException
, the option enables the JVM to analyze the program's bytecode instructions to determine precisely which reference isnull
, and describes the source with a null-detail message. The null-detail message is calculated and returned byNullPointerException.getMessage()
, and will be printed as the exception message along with the method, filename, and line number. By default, this option is enabled. -XX:+ShowMessageBoxOnError
- Enables the display of a dialog box when the JVM experiences an irrecoverable error. This prevents the JVM from exiting and keeps the process active so that you can attach a debugger to it to investigate the cause of the error. By default, this option is disabled.
-XX:StartFlightRecording=
parameter=
value-
Starts a JFR recording for the Java application. This option is equivalent to the
JFR.start
diagnostic command that starts a recording during runtime. You can set the following parameter=
value entries when starting a JFR recording:delay=
time-
Specifies the delay between the Java application launch time and the
start of the recording. Append
s
to specify the time in seconds,m
for minutes,h
for hours, ord
for days (for example, specifying10m
means 10 minutes). By default, there's no delay, and this parameter is set to 0. disk=
{true
|false
}- Specifies whether to write data to disk while recording. By default, this parameter is enabled.
dumponexit=
{true
|false
}-
Specifies if the running recording is dumped when the JVM shuts down. If
enabled and a
filename
is not entered, the recording is written to a file in the directory where the process was started. The file name is a system-generated name that contains the process ID, recording ID, and current timestamp, similar tohotspot-pid-47496-id-1-2018_01_25_19_10_41.jfr
. By default, this parameter is disabled. duration=
time-
Specifies the duration of the recording. Append
s
to specify the time in seconds,m
for minutes,h
for hours, ord
for days (for example, specifying5h
means 5 hours). By default, the duration isn't limited, and this parameter is set to 0. filename=
path-
Specifies the path and name of the file to which the recording is written when the recording is stopped, for example:
recording.jfr
/home/user/recordings/recording.jfr
c:\recordings\recording.jfr
If %p and/or %t is specified in the filename, it expands to the JVM's PID and the current timestamp, respectively.
name=
identifier- Takes both the name and the identifier of a recording.
maxage=
time-
Specifies the maximum age of disk data to keep for the recording. This
parameter is valid only when the
disk
parameter is set totrue
. Appends
to specify the time in seconds,m
for minutes,h
for hours, ord
for days (for example, specifying30s
means 30 seconds). By default, the maximum age isn't limited, and this parameter is set to0s
. maxsize=
size-
Specifies the maximum size (in bytes) of disk data to keep for the
recording. This parameter is valid only when the
disk
parameter is set totrue
. The value must not be less than the value for themaxchunksize
parameter set with-XX:FlightRecorderOptions
. Appendm
orM
to specify the size in megabytes, org
orG
to specify the size in gigabytes. By default, the maximum size of disk data isn't limited, and this parameter is set to0
. path-to-gc-roots=
{true
|false
}-
Specifies whether to collect the path to garbage collection (GC) roots at the end of a recording. By default, this parameter is disabled.
The path to GC roots is useful for finding memory leaks, but collecting it is time-consuming. Enable this option only when you start a recording for an application that you suspect has a memory leak. If the
settings
parameter is set toprofile
, the stack trace from where the potential leaking object was allocated is included in the information collected. settings=
path-
Specifies the path and name of the event settings file (of type JFC). By default, the
default.jfc
file is used, which is located inJAVA_HOME/lib/jfr
. This default settings file collects a predefined set of information with low overhead, so it has minimal impact on performance and can be used with recordings that run continuously.A second settings file is also provided, profile.jfc, which provides more data than the default configuration, but can have more overhead and impact performance. Use this configuration for short periods of time when more information is needed.
You can specify values for multiple parameters by separating them with a comma. Event settings and .jfc options can be specified using the following syntax:
option=
value-
Specifies the option value to modify. To list available options, use the
JAVA_HOME
/bin/jfr tool. event-setting=
value-
Specifies the event setting value to modify. Use the form:
<event-name>#<setting-name>=<value>
. To add a new event setting, prefix the event name with '+'.
You can specify values for multiple event settings and .jfc options by separating them with a comma. In case of a conflict between a parameter and a .jfc option, the parameter will take precedence. The whitespace delimiter can be omitted for timespan values, i.e. 20ms. For more information about the settings syntax, see Javadoc of the jdk.jfr package.
-XX:ThreadStackSize=
size-
Sets the Java thread stack size (in kilobytes). Use of a scaling suffix, such as
k
, results in the scaling of the kilobytes value so that-XX:ThreadStackSize=1k
sets the Java thread stack size to 1024*1024 bytes or 1 megabyte. The default value depends on the platform. For example:Linux/x64: 1024 KB
Linux/Aarch64: 2048 KB
macOS/x64: 1024 KB
macOS/Aarch64: 2048 KB
Windows: The default value depends on virtual memory
The following examples show how to set the thread stack size to 1 megabyte in different units:
-XX:ThreadStackSize=1k -XX:ThreadStackSize=1024
This option is similar to
-Xss
. -XX:-UseCompressedOops
-
Disables the use of compressed pointers. By default, this option is enabled, and compressed pointers are used. This will automatically limit the maximum ergonomically determined Java heap size to the maximum amount of memory that can be covered by compressed pointers. By default this range is 32 GB.
With compressed oops enabled, object references are represented as 32-bit offsets instead of 64-bit pointers, which typically increases performance when running the application with Java heap sizes smaller than the compressed oops pointer range. This option works only for 64-bit JVMs.
It's possible to use compressed pointers with Java heap sizes greater than 32 GB. See the
-XX:ObjectAlignmentInBytes
option. -XX:-UseContainerSupport
-
Linux only: The VM now provides automatic container detection support, which allows the VM to determine the amount of memory and number of processors that are available to a Java process running in docker containers. It uses this information to allocate system resources. The default for this flag is
true
, and container support is enabled by default. It can be disabled with-XX:-UseContainerSupport
.Unified Logging is available to help to diagnose issues related to this support.
Use
-Xlog:os+container=trace
for maximum logging of container information. See Enable Logging with the JVM Unified Logging Framework for a description of using Unified Logging. -XX:+UseLargePages
-
Enables the use of large page memory. By default, this option is disabled and large page memory isn't used.
See Large Pages.
-XX:+UseTransparentHugePages
- Linux only: Enables the use of large pages that can dynamically grow or shrink. This option is disabled by default. You may encounter performance problems with transparent huge pages as the OS moves other pages around to create huge pages; this option is made available for experimentation.
-XX:+AllowUserSignalHandlers
- Non-Windows: Enables installation of signal handlers by the application. By default, this option is disabled and the application isn't allowed to install signal handlers.
-XX:VMOptionsFile=
filename-
Allows user to specify VM options in a file, for example,
java -XX:VMOptionsFile=/var/my_vm_options HelloWorld
. -XX:UseBranchProtection=
mode-
Linux AArch64 only: Specifies the branch protection mode. All options other than
none
require the VM to have been built with branch protection enabled. In addition, for full protection, any native libraries provided by applications should be compiled with the same level of protection.Possible mode arguments for this option include the following:
none
- Do not use branch protection. This is the default value.
standard
- Enables all branch protection modes available on the current platform.
pac-ret
- Enables protection against ROP based attacks. (AArch64 8.3+ only)
Enabling the Graal JIT Compiler
The Graal JIT compiler provides optimized performance through advanced approaches to code analysis and optimization. It includes multiple optimization algorithms, such as aggressive inlining, polymorphic inlining, and others. (For more information about the Graal JIT compiler, see Graal Compiler.)
To enable the Graal JIT compiler, use the
-XX:+UseGraalJIT
option. (The -XX:+UseGraalJIT
option has to be used together with the
-XX:+UnlockExperimentalVMOptions
option that unlocks
experimental options.) The following example runs the Java application
com.example.myapp
with the Graal JIT compiler enabled:
java -XX:+UnlockExperimentalVMOptions -XX:+UseGraalJIT com.example.myapp
Configuring the Graal JIT Compiler
Because of its unique approach, some advanced JIT compiler options
for java
are incompatible with the Graal JIT
compiler--these are identified below. (For a list of Graal JIT compiler
options, see Graal
Compiler Configuration.)
Unlike the default compiler, the Graal JIT compiler is mostly
configured by system properties whose names begin with the
jdk.graal
prefix, set via -Djdk.graal...
on
the command line. The full list of available properties can be printed
using the -XX:+JVMCIPrintProperties
option.
Advanced JIT Compiler Options for java
These java
options control the dynamic just-in-time
(JIT) compilation performed by the Java HotSpot VM.
-XX:AllocateInstancePrefetchLines=
lines-
Sets the number of lines to prefetch ahead of the instance allocation pointer. By default, the number of lines to prefetch is set to 1:
-XX:AllocateInstancePrefetchLines=1
-XX:AllocatePrefetchDistance=
size-
Sets the size (in bytes) of the prefetch distance for object allocation. Memory about to be written with the value of new objects is prefetched up to this distance starting from the address of the last allocated object. Each Java thread has its own allocation point.
Negative values denote that prefetch distance is chosen based on the platform. Positive values are bytes to prefetch. Append the letter
k
orK
to indicate kilobytes,m
orM
to indicate megabytes, org
orG
to indicate gigabytes. The default value is set to -1.The following example shows how to set the prefetch distance to 1024 bytes:
-XX:AllocatePrefetchDistance=1024
-XX:AllocatePrefetchInstr=
instruction-
Sets the prefetch instruction to prefetch ahead of the allocation pointer. Possible values are from 0 to 3. The actual instructions behind the values depend on the platform. By default, the prefetch instruction is set to 0:
-XX:AllocatePrefetchInstr=0
-XX:AllocatePrefetchLines=
lines-
Sets the number of cache lines to load after the last object allocation by using the prefetch instructions generated in compiled code. The default value is 1 if the last allocated object was an instance, and 3 if it was an array.
The following example shows how to set the number of loaded cache lines to 5:
-XX:AllocatePrefetchLines=5
-XX:AllocatePrefetchStepSize=
size-
Sets the step size (in bytes) for sequential prefetch instructions. Append the letter
k
orK
to indicate kilobytes,m
orM
to indicate megabytes,g
orG
to indicate gigabytes. By default, the step size is set to 16 bytes:-XX:AllocatePrefetchStepSize=16
-XX:AllocatePrefetchStyle=
style-
Sets the generated code style for prefetch instructions. The style argument is an integer from 0 to 3:
0
- Don't generate prefetch instructions.
1
- Execute prefetch instructions after each allocation. This is the default setting.
2
- Use the thread-local allocation block (TLAB) watermark pointer to determine when prefetch instructions are executed.
3
- Generate one prefetch instruction per cache line.
-XX:+BackgroundCompilation
-
Enables background compilation. This option is enabled by default. To
disable background compilation, specify
-XX:-BackgroundCompilation
(this is equivalent to specifying-Xbatch
). -XX:CICompilerCount=
threads-
Sets the number of compiler threads to use for compilation. By default, the number of compiler threads is selected automatically depending on the number of CPUs and memory available for compiled code. The following example shows how to set the number of threads to 2:
-XX:CICompilerCount=2
If you have enabled the Graal JIT compiler, see
-XX:JVMCIThreads
. (See Enabling the Graal JIT Compiler for a description of how to enable and disable the Graal JIT compiler.) -XX:+UseDynamicNumberOfCompilerThreads
-
Dynamically create compiler thread up to the limit specified by
-XX:CICompilerCount
. This option is enabled by default. -XX:CompileCommand=
command,
method[,
option]-
Specifies a command to perform on a method. For example, to exclude the
indexOf()
method of theString
class from being compiled, use the following:-XX:CompileCommand=exclude,java/lang/String.indexOf
Note that the full class name is specified, including all packages and subpackages separated by a slash (
/
). For easier cut-and-paste operations, it's also possible to use the method name format produced by the-XX:+PrintCompilation
and-XX:+LogCompilation
options:-XX:CompileCommand=exclude,java.lang.String::indexOf
If the method is specified without the signature, then the command is applied to all methods with the specified name. However, you can also specify the signature of the method in the class file format. In this case, you should enclose the arguments in quotation marks, because otherwise the shell treats the semicolon as a command end. For example, if you want to exclude only the
indexOf(String)
method of theString
class from being compiled, use the following:-XX:CompileCommand="exclude,java/lang/String.indexOf,(Ljava/lang/String;)I"
You can also use the asterisk (*) as a wildcard for class and method names. For example, to exclude all
indexOf()
methods in all classes from being compiled, use the following:-XX:CompileCommand=exclude,*.indexOf
The commas and periods are aliases for spaces, making it easier to pass compiler commands through a shell. You can pass arguments to
-XX:CompileCommand
using spaces as separators by enclosing the argument in quotation marks:-XX:CompileCommand="exclude java/lang/String indexOf"
Note that after parsing the commands passed on the command line using the
-XX:CompileCommand
options, the JIT compiler then reads commands from the.hotspot_compiler
file. You can add commands to this file or specify a different file using the-XX:CompileCommandFile
option.To add several commands, either specify the
-XX:CompileCommand
option multiple times, or separate each argument with the new line separator (\n
). The following commands are available:break
- Sets a breakpoint when debugging the JVM to stop at the beginning of compilation of the specified method.
compileonly
-
Excludes all methods from compilation except for the specified method.
As an alternative, you can use the
-XX:CompileOnly
option, which lets you specify several methods. dontinline
- Prevents inlining of the specified method.
exclude
- Excludes the specified method from compilation.
help
-
Prints a help message for the
-XX:CompileCommand
option. inline
- Attempts to inline the specified method.
log
-
Excludes compilation logging (with the
-XX:+LogCompilation
option) for all methods except for the specified method. By default, logging is performed for all compiled methods. option
-
Passes a JIT compilation option to the specified method in place of the last argument (
option
). The compilation option is set at the end, after the method name. For example, to enable theBlockLayoutByFrequency
option for theappend()
method of theStringBuffer
class, use the following:-XX:CompileCommand=option,java/lang/StringBuffer.append,BlockLayoutByFrequency
You can specify multiple compilation options, separated by commas or spaces.
print
- Prints generated assembler code after compilation of the specified method.
quiet
-
Instructs not to print the compile commands. By default, the commands that you specify with the
-XX:CompileCommand
option are printed; for example, if you exclude from compilation theindexOf()
method of theString
class, then the following is printed to standard output:CompilerOracle: exclude java/lang/String.indexOf
You can suppress this by specifying the
-XX:CompileCommand=quiet
option before other-XX:CompileCommand
options.
-XX:CompileCommandFile=
filename-
Sets the file from which JIT compiler commands are read. By default, the
.hotspot_compiler
file is used to store commands performed by the JIT compiler.Each line in the command file represents a command, a class name, and a method name for which the command is used. For example, this line prints assembly code for the
toString()
method of theString
class:print java/lang/String toString
If you're using commands for the JIT compiler to perform on methods, then see the
-XX:CompileCommand
option. -XX:CompilerDirectivesFile=
file-
Adds directives from a file to the directives stack when a program starts. See Compiler Control.
The
-XX:CompilerDirectivesFile
option has to be used together with the-XX:UnlockDiagnosticVMOptions
option that unlocks diagnostic JVM options.The
-XX:CompilerDirectivesFile
option is not compatible with the Graal JIT compiler. If you have enabled the Graal JIT compiler, this option is ignored. (See Enabling the Graal JIT Compiler for a description of how to enable and disable the Graal JIT compiler.) -XX:+CompilerDirectivesPrint
-
Prints the directives stack when the program starts or when a new directive is added.
The
-XX:+CompilerDirectivesPrint
option has to be used together with the-XX:UnlockDiagnosticVMOptions
option that unlocks diagnostic JVM options.The
-XX:+CompilerDirectivesPrint
option is not compatible with the Graal JIT compiler. If you have enabled the Graal JIT compiler, this option is ignored. (See Enabling the Graal JIT Compiler for a description of how to enable and disable the Graal JIT compiler.) -XX:CompileOnly=
methods-
Sets the list of methods (separated by commas) to which compilation should be restricted. Only the specified methods are compiled.
-XX:CompileOnly=method1,method2,...,methodN
is an alias for:-XX:CompileCommand=compileonly,method1 -XX:CompileCommand=compileonly,method2 ... -XX:CompileCommand=compileonly,methodN
-XX:CompileThresholdScaling=
scale-
Provides unified control of first compilation. This option controls when
methods are first compiled for both the tiered and the nontiered modes
of operation. The
CompileThresholdScaling
option has a floating point value between 0 and +Inf and scales the thresholds corresponding to the current mode of operation (both tiered and nontiered). SettingCompileThresholdScaling
to a value less than 1.0 results in earlier compilation while values greater than 1.0 delay compilation. SettingCompileThresholdScaling
to 0 is equivalent to disabling compilation. -XX:+DoEscapeAnalysis
-
Enables the use of escape analysis. This option is enabled by default. To disable the use of escape analysis, specify
-XX:-DoEscapeAnalysis
.The
-XX:+DoEscapeAnalysis
option is not applicable to the Graal JIT compiler because it uses partial escape analysis. The Graal compiler has its own option-Djdk.graal.PartialEscapeAnalysis
. If you have enabled the Graal JIT compiler, this option is ignored. (See Enabling the Graal JIT Compiler for a description of how to enable and disable the Graal JIT compiler.) -XX:InitialCodeCacheSize=
size-
Sets the initial code cache size (in bytes). Append the letter
k
orK
to indicate kilobytes,m
orM
to indicate megabytes, org
orG
to indicate gigabytes. The default value depends on the platform. The initial code cache size shouldn't be less than the system's minimal memory page size. The following example shows how to set the initial code cache size to 32 KB:-XX:InitialCodeCacheSize=32k
-XX:+Inline
-
Enables method inlining. This option is enabled by default to increase
performance. To disable method inlining, specify
-XX:-Inline
. -XX:InlineSmallCode=
size-
Sets the maximum code size (in bytes) for already compiled methods that may be inlined. This flag only applies to the C2 compiler. Append the letter
k
orK
to indicate kilobytes,m
orM
to indicate megabytes, org
orG
to indicate gigabytes. The default value depends on the platform and on whether tiered compilation is enabled. In the following example it is set to 1000 bytes:-XX:InlineSmallCode=1000
The
-XX:InlineSmallCode
option is not compatible with the Graal JIT compiler. If you have enabled the Graal JIT compiler, this option is ignored. (See Enabling the Graal JIT Compiler for a description of how to enable and disable the Graal JIT compiler.) -XX:+LogCompilation
-
Enables logging of compilation activity to a file named
hotspot.log
in the current working directory. You can specify a different log file path and name using the-XX:LogFile
option.By default, this option is disabled and compilation activity isn't logged. The
-XX:+LogCompilation
option has to be used together with the-XX:UnlockDiagnosticVMOptions
option that unlocks diagnostic JVM options.You can enable verbose diagnostic output with a message printed to the console every time a method is compiled by using the
-XX:+PrintCompilation
option.If you have enabled the Graal JIT compiler, output specific to the C2 compiler is omitted. (See Enabling the Graal JIT Compiler for a description of how to enable and disable the Graal JIT compiler.)
-XX:FreqInlineSize=
size-
Sets the maximum bytecode size (in bytes) of a hot method to be inlined. This flag only applies to the C2 compiler. Append the letter
k
orK
to indicate kilobytes,m
orM
to indicate megabytes, org
orG
to indicate gigabytes. The default value depends on the platform. In the following example it is set to 325 bytes:-XX:FreqInlineSize=325
-XX:JVMCIThreads
-
Override the number of threads the CompileBroker gives to the Graal JIT
compiler if you have enabled it. This is typically used to restrict the
Graal JIT compiler to a single thread (
-XX:JVMCIThreads=1
) to avoid interleaved logging output from the compiler. (See Enabling the Graal JIT Compiler for a description of how to enable and disable the Graal JIT compiler.) -XX:MaxInlineSize=
size-
Sets the maximum bytecode size (in bytes) of a cold method to be inlined. This flag only applies to the C2 compiler. Append the letter
k
orK
to indicate kilobytes,m
orM
to indicate megabytes, org
orG
to indicate gigabytes. By default, the maximum bytecode size is set to 35 bytes:-XX:MaxInlineSize=35
The
-XX:MaxInlineSize
option is not compatible with the Graal JIT compiler. If you have enabled the Graal JIT compiler, this option is ignored. (See Enabling the Graal JIT Compiler for a description of how to enable and disable the Graal JIT compiler.) -XX:C1MaxInlineSize=
size-
Sets the maximum bytecode size (in bytes) of a cold method to be inlined. This flag only applies to the C1 compiler. Append the letter
k
orK
to indicate kilobytes,m
orM
to indicate megabytes, org
orG
to indicate gigabytes. By default, the maximum bytecode size is set to 35 bytes:-XX:MaxInlineSize=35
The
-XX:C1MaxInlineSize
option is not compatible with the Graal JIT compiler. If you have enabled the Graal JIT compiler, this option is ignored. (See Enabling the Graal JIT Compiler for a description of how to enable and disable the Graal JIT compiler.) -XX:MaxTrivialSize=
size-
Sets the maximum bytecode size (in bytes) of a trivial method to be inlined. This flag only applies to the C2 compiler. Append the letter
k
orK
to indicate kilobytes,m
orM
to indicate megabytes, org
orG
to indicate gigabytes. By default, the maximum bytecode size of a trivial method is set to 6 bytes:-XX:MaxTrivialSize=6
The
-XX:MaxTrivialSize
option is not compatible with the Graal JIT compiler. If you have enabled the Graal JIT compiler, this option is ignored. (See Enabling the Graal JIT Compiler for a description of how to enable and disable the Graal JIT compiler.) -XX:C1MaxTrivialSize=
size-
Sets the maximum bytecode size (in bytes) of a trivial method to be inlined. This flag only applies to the C1 compiler. Append the letter
k
orK
to indicate kilobytes,m
orM
to indicate megabytes, org
orG
to indicate gigabytes. By default, the maximum bytecode size of a trivial method is set to 6 bytes:-XX:MaxTrivialSize=6
The
-XX:C1MaxTrivialSize
option is not compatible with the Graal JIT compiler. If you have enabled the Graal JIT compiler, this option is ignored. (See Enabling the Graal JIT Compiler for a description of how to enable and disable the Graal JIT compiler.) -XX:MaxNodeLimit=
nodes-
Sets the maximum number of nodes to be used during single method compilation. By default the value depends on the features enabled. In the following example the maximum number of nodes is set to 100,000:
-XX:MaxNodeLimit=100000
The
-XX:MaxNodeLimit
option is not compatible with the Graal JIT compiler. If you have enabled the Graal JIT compiler, this option is ignored. (See Enabling the Graal JIT Compiler for a description of how to enable and disable the Graal JIT compiler.) -XX:NonNMethodCodeHeapSize=
size-
Sets the size in bytes of the code segment containing nonmethod code.
A nonmethod code segment containing nonmethod code, such as compiler buffers and the bytecode interpreter. This code type stays in the code cache forever. This flag is used only if
-XX:SegmentedCodeCache
is enabled. -XX:NonProfiledCodeHeapSize=
size-
Sets the size in bytes of the code segment containing nonprofiled
methods. This flag is used only if
-XX:SegmentedCodeCache
is enabled. -XX:+OptimizeStringConcat
-
Enables the optimization of
String
concatenation operations. This option is enabled by default. To disable the optimization ofString
concatenation operations, specify-XX:-OptimizeStringConcat
.The
-XX:+OptimizeStringConcat
option is not applicable to the Graal JIT compiler. The Graal compiler has its own option-Djdk.graal.OptStringConcat
. If you have enabled the Graal JIT compiler, this option is ignored. (See Enabling the Graal JIT Compiler for a description of how to enable and disable the Graal JIT compiler.) -XX:+PrintAssembly
-
Enables printing of assembly code for bytecoded and native methods by using the external
hsdis-<arch>.so
or.dll
library. For 64-bit VM on Windows, it'shsdis-amd64.dll
. This lets you to see the generated code, which may help you to diagnose performance issues.By default, this option is disabled and assembly code isn't printed. The
-XX:+PrintAssembly
option has to be used together with the-XX:UnlockDiagnosticVMOptions
option that unlocks diagnostic JVM options. -XX:ProfiledCodeHeapSize=
size-
Sets the size in bytes of the code segment containing profiled methods.
This flag is used only if
-XX:SegmentedCodeCache
is enabled. -XX:+PrintCompilation
-
Enables verbose diagnostic output from the JVM by printing a message to the console every time a method is compiled. This lets you to see which methods actually get compiled. By default, this option is disabled and diagnostic output isn't printed.
You can also log compilation activity to a file by using the
-XX:+LogCompilation
option. -XX:+PrintInlining
-
Enables printing of inlining decisions. This let's you see which methods are getting inlined.
By default, this option is disabled and inlining information isn't printed. The
-XX:+PrintInlining
option has to be used together with the-XX:+UnlockDiagnosticVMOptions
option that unlocks diagnostic JVM options. -XX:ReservedCodeCacheSize=
size-
Sets the maximum code cache size (in bytes) for JIT-compiled code.
Append the letter
k
orK
to indicate kilobytes,m
orM
to indicate megabytes, org
orG
to indicate gigabytes. The default maximum code cache size is 240 MB; if you disable tiered compilation with the option-XX:-TieredCompilation
, then the default size is 48 MB. This option has a limit of 2 GB; otherwise, an error is generated. The maximum code cache size shouldn't be less than the initial code cache size; see the option-XX:InitialCodeCacheSize
. -XX:+SegmentedCodeCache
-
Enables segmentation of the code cache, without which the code cache consists of one large segment. With
-XX:+SegmentedCodeCache
, separate segments will be used for non-method, profiled method, and non-profiled method code. The segments are not resized at runtime. The advantages are better control of the memory footprint, reduced code fragmentation, and better CPU iTLB (instruction translation lookaside buffer) and instruction cache behavior due to improved locality.The feature is enabled by default if tiered compilation is enabled (
-XX:+TieredCompilation
) and the reserved code cache size (-XX:ReservedCodeCacheSize
) is at least 240 MB. -XX:StartAggressiveSweepingAt=
percent- Forces stack scanning of active methods to aggressively remove unused code when only the given percentage of the code cache is free. The default value is 10%.
-XX:-TieredCompilation
- Disables the use of tiered compilation. By default, this option is enabled.
-XX:UseSSE=
version- Enables the use of SSE instruction set of a specified version. Is set by default to the highest supported version available (x86 only).
-XX:UseAVX=
version- Enables the use of AVX instruction set of a specified version. Is set by default to the highest supported version available (x86 only).
-XX:+UseAES
-
Enables hardware-based AES intrinsics for hardware that supports it.
This option is on by default on hardware that has the necessary
instructions. The
-XX:+UseAES
is used in conjunction withUseAESIntrinsics
. Flags that control intrinsics now require the option-XX:+UnlockDiagnosticVMOptions
. -XX:+UseAESIntrinsics
-
Enables AES intrinsics. Specifying
-XX:+UseAESIntrinsics
is equivalent to also enabling-XX:+UseAES
. To disable hardware-based AES intrinsics, specify-XX:-UseAES -XX:-UseAESIntrinsics
. For example, to enable hardware AES, use the following flags:-XX:+UseAES -XX:+UseAESIntrinsics
Flags that control intrinsics now require the option
-XX:+UnlockDiagnosticVMOptions
. -XX:+UseAESCTRIntrinsics
-
Analogous to
-XX:+UseAESIntrinsics
enables AES/CTR intrinsics. -XX:+UseGHASHIntrinsics
-
Controls the use of GHASH intrinsics. Enabled by default on platforms
that support the corresponding instructions. Flags that control
intrinsics now require the option
-XX:+UnlockDiagnosticVMOptions
. -XX:+UseChaCha20Intrinsics
-
Enable ChaCha20 intrinsics. This option is on by default for supported
platforms. To disable ChaCha20 intrinsics, specify
-XX:-UseChaCha20Intrinsics
. Flags that control intrinsics now require the option-XX:+UnlockDiagnosticVMOptions
. -XX:+UsePoly1305Intrinsics
-
Enable Poly1305 intrinsics. This option is on by default for supported
platforms. To disable Poly1305 intrinsics, specify
-XX:-UsePoly1305Intrinsics
. Flags that control intrinsics now require the option-XX:+UnlockDiagnosticVMOptions
. -XX:+UseBASE64Intrinsics
-
Controls the use of accelerated BASE64 encoding routines for
java.util.Base64
. Enabled by default on platforms that support it. Flags that control intrinsics now require the option-XX:+UnlockDiagnosticVMOptions
. -XX:+UseAdler32Intrinsics
-
Controls the use of Adler32 checksum algorithm intrinsic for
java.util.zip.Adler32
. Enabled by default on platforms that support it. Flags that control intrinsics now require the option-XX:+UnlockDiagnosticVMOptions
. -XX:+UseCRC32Intrinsics
-
Controls the use of CRC32 intrinsics for
java.util.zip.CRC32
. Enabled by default on platforms that support it. Flags that control intrinsics now require the option-XX:+UnlockDiagnosticVMOptions
. -XX:+UseCRC32CIntrinsics
-
Controls the use of CRC32C intrinsics for
java.util.zip.CRC32C
. Enabled by default on platforms that support it. Flags that control intrinsics now require the option-XX:+UnlockDiagnosticVMOptions
. -XX:+UseSHA
-
Enables hardware-based intrinsics for SHA crypto hash functions for some hardware. The
UseSHA
option is used in conjunction with theUseSHA1Intrinsics
,UseSHA256Intrinsics
, andUseSHA512Intrinsics
options.The
UseSHA
andUseSHA*Intrinsics
flags are enabled by default on machines that support the corresponding instructions.This feature is applicable only when using the
sun.security.provider.Sun
provider for SHA operations. Flags that control intrinsics now require the option-XX:+UnlockDiagnosticVMOptions
.To disable all hardware-based SHA intrinsics, specify the
-XX:-UseSHA
. To disable only a particular SHA intrinsic, use the appropriate corresponding option. For example:-XX:-UseSHA256Intrinsics
. -XX:+UseSHA1Intrinsics
-
Enables intrinsics for SHA-1 crypto hash function. Flags that control
intrinsics now require the option
-XX:+UnlockDiagnosticVMOptions
. -XX:+UseSHA256Intrinsics
-
Enables intrinsics for SHA-224 and SHA-256 crypto hash functions. Flags
that control intrinsics now require the option
-XX:+UnlockDiagnosticVMOptions
. -XX:+UseSHA512Intrinsics
-
Enables intrinsics for SHA-384 and SHA-512 crypto hash functions. Flags
that control intrinsics now require the option
-XX:+UnlockDiagnosticVMOptions
. -XX:+UseMathExactIntrinsics
-
Enables intrinsification of various
java.lang.Math.*Exact()
functions. Enabled by default. Flags that control intrinsics now require the option-XX:+UnlockDiagnosticVMOptions
. -XX:+UseMultiplyToLenIntrinsic
-
Enables intrinsification of
BigInteger.multiplyToLen()
. Enabled by default on platforms that support it. Flags that control intrinsics now require the option-XX:+UnlockDiagnosticVMOptions
. - -XX:+UseSquareToLenIntrinsic
-
Enables intrinsification of
BigInteger.squareToLen()
. Enabled by default on platforms that support it. Flags that control intrinsics now require the option-XX:+UnlockDiagnosticVMOptions
. - -XX:+UseMulAddIntrinsic
-
Enables intrinsification of
BigInteger.mulAdd()
. Enabled by default on platforms that support it. Flags that control intrinsics now require the option-XX:+UnlockDiagnosticVMOptions
. - -XX:+UseMontgomeryMultiplyIntrinsic
-
Enables intrinsification of
BigInteger.montgomeryMultiply()
. Enabled by default on platforms that support it. Flags that control intrinsics now require the option-XX:+UnlockDiagnosticVMOptions
. - -XX:+UseMontgomerySquareIntrinsic
-
Enables intrinsification of
BigInteger.montgomerySquare()
. Enabled by default on platforms that support it. Flags that control intrinsics now require the option-XX:+UnlockDiagnosticVMOptions
. -XX:+UseCMoveUnconditionally
-
Generates CMove (scalar and vector) instructions regardless of profitability analysis.
The
-XX:+UseCMoveUnconditionally
option is not applicable to the Graal JIT compiler. The Graal compiler has its own option-Djdk.graal.CMoveALot
. If you have enabled the Graal JIT compiler, this option is ignored. (See Enabling the Graal JIT Compiler for a description of how to enable and disable the Graal JIT compiler.) -XX:+UseCodeCacheFlushing
-
Enables flushing of the code cache before shutting down the compiler.
This option is enabled by default. To disable flushing of the code cache
before shutting down the compiler, specify
-XX:-UseCodeCacheFlushing
. -XX:+UseCondCardMark
-
Enables checking if the card is already marked before updating the card table. This option is disabled by default. It should be used only on machines with multiple sockets, where it increases the performance of Java applications that rely on concurrent operations.
The
-XX:+UseCondCardMark
option is not implemented by the Graal JIT compiler. If you have enabled the Graal JIT compiler, this option is ignored. (See Enabling the Graal JIT Compiler for a description of how to enable and disable the Graal JIT compiler.) -XX:+UseCountedLoopSafepoints
-
Keeps safepoints in counted loops. Its default value depends on whether the selected garbage collector requires low latency safepoints.
The
-XX:+UseCountedLoopSafepoints
option is not applicable to the Graal JIT compiler. The Graal compiler has its own option-Djdk.graal.RemoveLoopSafepoints=true
to disable safepoint removal. Iffalse
, safepoints in counted loops are retained. If you have enabled the Graal JIT compiler, this option is ignored. (See Enabling the Graal JIT Compiler for a description of how to enable and disable the Graal JIT compiler.) -XX:LoopStripMiningIter=
number_of_iterations-
Controls the number of iterations in the inner strip mined loop. Strip mining transforms counted loops into two level nested loops. Safepoints are kept in the outer loop while the inner loop can execute at full speed. This option controls the maximum number of iterations in the inner loop. The default value is 1,000.
The
-XX:LoopStripMiningIter
option is not applicable to the Graal JIT compiler. The Graal compiler has its own option-Djdk.graal.CountedStripMiningInnerLoopTrips
. If you have enabled the Graal JIT compiler, this option is ignored. (See Enabling the Graal JIT Compiler for a description of how to enable and disable the Graal JIT compiler.) -XX:LoopStripMiningIterShortLoop=
number_of_iterations-
Controls loop strip mining optimization. Loops with the number of iterations less than specified will not have safepoints in them. Default value is 1/10th of
-XX:LoopStripMiningIter
.The
-XX:LoopStripMiningIterShortLoop
option is not applicable to the Graal JIT compiler. The Graal compiler's safepoint removal optimizations work on all loops so it does not have an option to treat strip-mined inner loops specially. If you have enabled the Graal JIT compiler, this option is ignored. (See Enabling the Graal JIT Compiler for a description of how to enable and disable the Graal JIT compiler.) -XX:+UseFMA
-
Enables hardware-based FMA intrinsics for hardware where FMA
instructions are available (such as, Intel and ARM64). FMA intrinsics
are generated for the
java.lang.Math.fma(
a,
b,
c)
methods that calculate the value of(
a*
b+
c)
expressions. -XX:+UseSuperWord
-
Enables the transformation of scalar operations into superword operations. Superword is a vectorization optimization. This option is enabled by default. To disable the transformation of scalar operations into superword operations, specify
-XX:-UseSuperWord
.The
-XX:+UseSuperWord
option is not applicable to the Graal JIT compiler. The Graal compiler has its own option-Djdk.graal.Vectorize
. If you have enabled the Graal JIT compiler, this option is ignored. (See Enabling the Graal JIT Compiler for a description of how to enable and disable the Graal JIT compiler.)
Advanced Serviceability Options for Java
These java
options provide the ability to gather system
information and perform extensive debugging.
-XX:+DisableAttachMechanism
-
Disables the mechanism that lets tools attach to the JVM. By default, this option is disabled, meaning that the attach mechanism is enabled and you can use diagnostics and troubleshooting tools such as
jcmd
,jstack
,jmap
, andjinfo
.Note: The tools such as jcmd, jinfo, jmap, and jstack shipped with the JDK aren't supported when using the tools from one JDK version to troubleshoot a different JDK version.
-XX:+DTraceAllocProbes
-
Linux and macOS: Enable
dtrace
tool probes for object allocation. -XX:+DTraceMethodProbes
-
Linux and macOS: Enable
dtrace
tool probes for method-entry and method-exit. -XX:+DTraceMonitorProbes
-
Linux and macOS: Enable
dtrace
tool probes for monitor events. -XX:+HeapDumpOnOutOfMemoryError
-
Enables the dumping of the Java heap to a file in the current directory
by using the heap profiler (HPROF) when a
java.lang.OutOfMemoryError
exception is thrown. You can explicitly set the heap dump file path and name using the-XX:HeapDumpPath
option. By default, this option is disabled and the heap isn't dumped when anOutOfMemoryError
exception is thrown. -XX:HeapDumpPath=
path-
Sets the path and file name for writing the heap dump provided by the heap profiler (HPROF) when the
-XX:+HeapDumpOnOutOfMemoryError
option is set. By default, the file is created in the current working directory, and it's namedjava_pid<pid>.hprof
where<pid>
is the identifier of the process that caused the error. The following example shows how to set the default file explicitly (%p
represents the current process identifier):-XX:HeapDumpPath=./java_pid%p.hprof
Non-Windows: The following example shows how to set the heap dump file to
/var/log/java/java_heapdump.hprof
:-XX:HeapDumpPath=/var/log/java/java_heapdump.hprof
Windows: The following example shows how to set the heap dump file to
C:/log/java/java_heapdump.log
:-XX:HeapDumpPath=C:/log/java/java_heapdump.log
-XX:LogFile=
path-
Sets the path and file name to where log data is written. By default, the file is created in the current working directory, and it's named
hotspot.log
.Non-Windows: The following example shows how to set the log file to
/var/log/java/hotspot.log
:-XX:LogFile=/var/log/java/hotspot.log
Windows: The following example shows how to set the log file to
C:/log/java/hotspot.log
:-XX:LogFile=C:/log/java/hotspot.log
-XX:+PrintClassHistogram
-
Enables printing of a class instance histogram after one of the following events:
Non-Windows:
Control+\
(SIGQUIT
)Windows:
Control+C
(SIGTERM
)
By default, this option is disabled.
Setting this option is equivalent to running the
jmap -histo
command, or thejcmd
pidGC.class_histogram
command, where pid is the current Java process identifier. -XX:+PrintConcurrentLocks
-
Enables printing of
java.util.concurrent
locks after one of the following events:Non-Windows:
Control+\
(SIGQUIT
)Windows:
Control+C
(SIGTERM
)
By default, this option is disabled.
Setting this option is equivalent to running the
jstack -l
command or thejcmd
pidThread.print -l
command, where pid is the current Java process identifier. -XX:+PrintFlagsRanges
- Prints the range specified and allows automatic testing of the values. See Validate Java Virtual Machine Flag Arguments.
-XX:+PerfDataSaveToFile
-
If enabled, saves jstat binary data when the Java application exits. This binary data is saved in a file named
hsperfdata_
pid, where pid is the process identifier of the Java application that you ran. Use thejstat
command to display the performance data contained in this file as follows:jstat -class file:///
path/hsperfdata_
pidjstat -gc file:///
path/hsperfdata_
pid -XX:+UsePerfData
-
Enables the
perfdata
feature. This option is enabled by default to allow JVM monitoring and performance testing. Disabling it suppresses the creation of thehsperfdata_userid
directories. To disable theperfdata
feature, specify-XX:-UsePerfData
.
Advanced Garbage Collection Options for Java
These java
options control how garbage collection (GC)
is performed by the Java HotSpot VM.
-XX:+AggressiveHeap
- Enables Java heap optimization. This sets various parameters to be optimal for long-running jobs with intensive memory allocation, based on the configuration of the computer (RAM and CPU). By default, the option is disabled and the heap sizes are configured less aggressively.
-XX:+AlwaysPreTouch
- Requests the VM to touch every page on the Java heap after requesting it from the operating system and before handing memory out to the application. By default, this option is disabled and all pages are committed as the application uses the heap space.
-XX:ConcGCThreads=
threads-
Sets the number of threads used for concurrent GC. Sets
threads
to approximately 1/4 of the number of parallel garbage collection threads. The default value depends on the number of CPUs available to the JVM.For example, to set the number of threads for concurrent GC to 2, specify the following option:
-XX:ConcGCThreads=2
-XX:+DisableExplicitGC
-
Enables the option that disables processing of calls to the
System.gc()
method. This option is disabled by default, meaning that calls toSystem.gc()
are processed. If processing of calls toSystem.gc()
is disabled, then the JVM still performs GC when necessary. -XX:+ExplicitGCInvokesConcurrent
-
Enables invoking of concurrent GC by using the
System.gc()
request. This option is disabled by default and can be enabled only with the-XX:+UseG1GC
option. -XX:G1AdaptiveIHOPNumInitialSamples=
number-
When
-XX:UseAdaptiveIHOP
is enabled, this option sets the number of completed marking cycles used to gather samples until G1 adaptively determines the optimum value of-XX:InitiatingHeapOccupancyPercent
. Before, G1 uses the value of-XX:InitiatingHeapOccupancyPercent
directly for this purpose. The default value is 3. -XX:G1HeapRegionSize=
size-
Sets the size of the regions into which the Java heap is subdivided when using the garbage-first (G1) collector. The value is a power of 2 and can range from 1 MB to 32 MB. The default region size is determined ergonomically based on the heap size with a goal of approximately 2048 regions.
The following example sets the size of the subdivisions to 16 MB:
-XX:G1HeapRegionSize=16m
-XX:G1HeapWastePercent=
percent- Sets the percentage of heap that you're willing to waste. The Java HotSpot VM doesn't initiate the mixed garbage collection cycle when the reclaimable percentage is less than the heap waste percentage. The default is 5 percent.
-XX:G1MaxNewSizePercent=
percent-
Sets the percentage of the heap size to use as the maximum for the young generation size. The default value is 60 percent of your Java heap.
This is an experimental flag. This setting replaces the
-XX:DefaultMaxNewGenPercent
setting. -XX:G1MixedGCCountTarget=
number-
Sets the target number of mixed garbage collections after a marking
cycle to collect old regions with at most
G1MixedGCLIveThresholdPercent
live data. The default is 8 mixed garbage collections. The goal for mixed collections is to be within this target number. -XX:G1MixedGCLiveThresholdPercent=
percent-
Sets the occupancy threshold for an old region to be included in a mixed garbage collection cycle. The default occupancy is 85 percent.
This is an experimental flag. This setting replaces the
-XX:G1OldCSetRegionLiveThresholdPercent
setting. -XX:G1NewSizePercent=
percent-
Sets the percentage of the heap to use as the minimum for the young generation size. The default value is 5 percent of your Java heap.
This is an experimental flag. This setting replaces the
-XX:DefaultMinNewGenPercent
setting. -XX:G1OldCSetRegionThresholdPercent=
percent- Sets an upper limit on the number of old regions to be collected during a mixed garbage collection cycle. The default is 10 percent of the Java heap.
-XX:G1ReservePercent=
percent-
Sets the percentage of the heap (0 to 50) that's reserved as a false ceiling to reduce the possibility of promotion failure for the G1 collector. When you increase or decrease the percentage, ensure that you adjust the total Java heap by the same amount. By default, this option is set to 10%.
The following example sets the reserved heap to 20%:
-XX:G1ReservePercent=20
-XX:+G1UseAdaptiveIHOP
-
Controls adaptive calculation of the old generation occupancy to start background work preparing for an old generation collection. If enabled, G1 uses
-XX:InitiatingHeapOccupancyPercent
for the first few times as specified by the value of-XX:G1AdaptiveIHOPNumInitialSamples
, and after that adaptively calculates a new optimum value for the initiating occupancy automatically. Otherwise, the old generation collection process always starts at the old generation occupancy determined by-XX:InitiatingHeapOccupancyPercent
.The default is enabled.
-XX:InitialHeapSize=
size-
Sets the initial size (in bytes) of the memory allocation pool. This value must be either 0, or a multiple of 1024 and greater than 1 MB. Append the letter
k
orK
to indicate kilobytes,m
orM
to indicate megabytes, org
orG
to indicate gigabytes. The default value is selected at run time based on the system configuration.The following examples show how to set the size of allocated memory to 6 MB using various units:
-XX:InitialHeapSize=6291456 -XX:InitialHeapSize=6144k -XX:InitialHeapSize=6m
If you set this option to 0, then the initial size is set as the sum of the sizes allocated for the old generation and the young generation. The size of the heap for the young generation can be set using the
-XX:NewSize
option. Note that the-Xms
option sets both the minimum and the initial heap size of the heap. If-Xms
appears after-XX:InitialHeapSize
on the command line, then the initial heap size gets set to the value specified with-Xms
. -XX:InitialRAMPercentage=
percent-
Sets the initial amount of memory that the JVM will use for the Java heap before applying ergonomics heuristics as a percentage of the maximum amount determined as described in the
-XX:MaxRAM
option. The default value is 1.5625 percent.The following example shows how to set the percentage of the initial amount of memory used for the Java heap:
-XX:InitialRAMPercentage=5
-XX:InitialSurvivorRatio=
ratio-
Sets the initial survivor space ratio used by the throughput garbage collector (which is enabled by the
-XX:+UseParallelGC
option). Adaptive sizing is enabled by default with the throughput garbage collector by using the-XX:+UseParallelGC
option, and the survivor space is resized according to the application behavior, starting with the initial value. If adaptive sizing is disabled (using the-XX:-UseAdaptiveSizePolicy
option), then the-XX:SurvivorRatio
option should be used to set the size of the survivor space for the entire execution of the application.The following formula can be used to calculate the initial size of survivor space (S) based on the size of the young generation (Y), and the initial survivor space ratio (R):
S=Y/(R+2)
The 2 in the equation denotes two survivor spaces. The larger the value specified as the initial survivor space ratio, the smaller the initial survivor space size.
By default, the initial survivor space ratio is set to 8. If the default value for the young generation space size is used (2 MB), then the initial size of the survivor space is 0.2 MB.
The following example shows how to set the initial survivor space ratio to 4:
-XX:InitialSurvivorRatio=4
-XX:InitiatingHeapOccupancyPercent=
percent-
Sets the percentage of the old generation occupancy (0 to 100) at which to start the first few concurrent marking cycles for the G1 garbage collector.
By default, the initiating value is set to 45%. A value of 0 implies nonstop concurrent GC cycles from the beginning until G1 adaptively sets this value.
See also the
-XX:G1UseAdaptiveIHOP
and-XX:G1AdaptiveIHOPNumInitialSamples
options.The following example shows how to set the initiating heap occupancy to 75%:
-XX:InitiatingHeapOccupancyPercent=75
-XX:MaxGCPauseMillis=
time-
Sets a target for the maximum GC pause time (in milliseconds). This is a soft goal, and the JVM will make its best effort to achieve it. The specified value doesn't adapt to your heap size. By default, for G1 the maximum pause time target is 200 milliseconds. The other generational collectors do not use a pause time goal by default.
The following example shows how to set the maximum target pause time to 500 ms:
-XX:MaxGCPauseMillis=500
-XX:MaxHeapSize=
size-
Sets the maximum size (in byes) of the memory allocation pool. This value must be a multiple of 1024 and greater than 2 MB. Append the letter
k
orK
to indicate kilobytes,m
orM
to indicate megabytes, org
orG
to indicate gigabytes. The default value is selected at run time based on the system configuration. For server deployments, the options-XX:InitialHeapSize
and-XX:MaxHeapSize
are often set to the same value.The following examples show how to set the maximum allowed size of allocated memory to 80 MB using various units:
-XX:MaxHeapSize=83886080 -XX:MaxHeapSize=81920k -XX:MaxHeapSize=80m
The
-XX:MaxHeapSize
option is equivalent to-Xmx
. -XX:MaxHeapFreeRatio=
percent-
Sets the maximum allowed percentage of free heap space (0 to 100) after a GC event. If free heap space expands above this value, then the heap is shrunk. By default, this value is set to 70%.
Minimize the Java heap size by lowering the values of the parameters
MaxHeapFreeRatio
(default value is 70%) andMinHeapFreeRatio
(default value is 40%) with the command-line options-XX:MaxHeapFreeRatio
and-XX:MinHeapFreeRatio
. LoweringMaxHeapFreeRatio
to as low as 10% andMinHeapFreeRatio
to 5% has successfully reduced the heap size without too much performance regression; however, results may vary greatly depending on your application. Try different values for these parameters until they're as low as possible yet still retain acceptable performance.-XX:MaxHeapFreeRatio=10 -XX:MinHeapFreeRatio=5
Customers trying to keep the heap small should also add the option
-XX:-ShrinkHeapInSteps
. See Performance Tuning Examples for a description of using this option to keep the Java heap small by reducing the dynamic footprint for embedded applications. -XX:MaxMetaspaceSize=
size-
Sets the maximum amount of native memory that can be allocated for class metadata. By default, the size isn't limited. The amount of metadata for an application depends on the application itself, other running applications, and the amount of memory available on the system.
The following example shows how to set the maximum class metadata size to 256 MB:
-XX:MaxMetaspaceSize=256m
-XX:MaxNewSize=
size- Sets the maximum size (in bytes) of the heap for the young generation (nursery). The default value is set ergonomically.
-XX:MaxRAM=
size-
Sets the maximum amount of memory that the JVM may use for the Java heap before applying ergonomics heuristics. The default value is the maximum amount of available memory to the JVM process or 128 GB, whichever is lower.
The maximum amount of available memory to the JVM process is the minimum of the machine's physical memory and any constraints set by the environment (e.g. container).
Specifying this option disables automatic use of compressed oops if the combined result of this and other options influencing the maximum amount of memory is larger than the range of memory addressable by compressed oops. See
-XX:UseCompressedOops
for further information about compressed oops.The following example shows how to set the maximum amount of available memory for sizing the Java heap to 2 GB:
-XX:MaxRAM=2G
-XX:MaxRAMPercentage=
percent-
Sets the maximum amount of memory that the JVM may use for the Java heap before applying ergonomics heuristics as a percentage of the maximum amount determined as described in the
-XX:MaxRAM
option. The default value is 25 percent.Specifying this option disables automatic use of compressed oops if the combined result of this and other options influencing the maximum amount of memory is larger than the range of memory addressable by compressed oops. See
-XX:UseCompressedOops
for further information about compressed oops.The following example shows how to set the percentage of the maximum amount of memory used for the Java heap:
-XX:MaxRAMPercentage=75
-XX:MinRAMPercentage=
percent-
Sets the maximum amount of memory that the JVM may use for the Java heap before applying ergonomics heuristics as a percentage of the maximum amount determined as described in the
-XX:MaxRAM
option for small heaps. A small heap is a heap of approximately 125 MB. The default value is 50 percent.The following example shows how to set the percentage of the maximum amount of memory used for the Java heap for small heaps:
-XX:MinRAMPercentage=75
-XX:MaxTenuringThreshold=
threshold-
Sets the maximum tenuring threshold for use in adaptive GC sizing. The largest value is 15. The default value is 15 for the parallel (throughput) collector.
The following example shows how to set the maximum tenuring threshold to 10:
-XX:MaxTenuringThreshold=10
-XX:MetaspaceSize=
size- Sets the size of the allocated class metadata space that triggers a garbage collection the first time it's exceeded. This threshold for a garbage collection is increased or decreased depending on the amount of metadata used. The default size depends on the platform.
-XX:MinHeapFreeRatio=
percent-
Sets the minimum allowed percentage of free heap space (0 to 100) after a GC event. If free heap space falls below this value, then the heap is expanded. By default, this value is set to 40%.
Minimize Java heap size by lowering the values of the parameters
MaxHeapFreeRatio
(default value is 70%) andMinHeapFreeRatio
(default value is 40%) with the command-line options-XX:MaxHeapFreeRatio
and-XX:MinHeapFreeRatio
. LoweringMaxHeapFreeRatio
to as low as 10% andMinHeapFreeRatio
to 5% has successfully reduced the heap size without too much performance regression; however, results may vary greatly depending on your application. Try different values for these parameters until they're as low as possible, yet still retain acceptable performance.-XX:MaxHeapFreeRatio=10 -XX:MinHeapFreeRatio=5
Customers trying to keep the heap small should also add the option
-XX:-ShrinkHeapInSteps
. See Performance Tuning Examples for a description of using this option to keep the Java heap small by reducing the dynamic footprint for embedded applications. -XX:MinHeapSize=
size-
Sets the minimum size (in bytes) of the memory allocation pool. This value must be either 0, or a multiple of 1024 and greater than 1 MB. Append the letter
k
orK
to indicate kilobytes,m
orM
to indicate megabytes, org
orG
to indicate gigabytes. The default value is selected at run time based on the system configuration.The following examples show how to set the minimum size of allocated memory to 6 MB using various units:
-XX:MinHeapSize=6291456 -XX:MinHeapSize=6144k -XX:MinHeapSize=6m
If you set this option to 0, then the minimum size is set to the same value as the initial size.
-XX:NewRatio=
ratio-
Sets the ratio between young and old generation sizes. By default, this option is set to 2. The following example shows how to set the young-to-old ratio to 1:
-XX:NewRatio=1
-XX:NewSize=
size-
Sets the initial size (in bytes) of the heap for the young generation (nursery). Append the letter
k
orK
to indicate kilobytes,m
orM
to indicate megabytes, org
orG
to indicate gigabytes.The young generation region of the heap is used for new objects. GC is performed in this region more often than in other regions. If the size for the young generation is too low, then a large number of minor GCs are performed. If the size is too high, then only full GCs are performed, which can take a long time to complete. It is recommended that you keep the size for the young generation greater than 25% and less than 50% of the overall heap size.
The following examples show how to set the initial size of the young generation to 256 MB using various units:
-XX:NewSize=256m -XX:NewSize=262144k -XX:NewSize=268435456
The
-XX:NewSize
option is equivalent to-Xmn
. -XX:ParallelGCThreads=
threads-
Sets the number of the stop-the-world (STW) worker threads. The default value depends on the number of CPUs available to the JVM and the garbage collector selected.
For example, to set the number of threads for G1 GC to 2, specify the following option:
-XX:ParallelGCThreads=2
-XX:+ParallelRefProcEnabled
- Enables parallel reference processing. By default, this option is disabled.
-XX:+PrintAdaptiveSizePolicy
- Enables printing of information about adaptive-generation sizing. By default, this option is disabled.
-XX:SoftRefLRUPolicyMSPerMB=
time-
Sets the amount of time (in milliseconds) a softly reachable object is kept active on the heap after the last time it was referenced. The default value is one second of lifetime per free megabyte in the heap. The
-XX:SoftRefLRUPolicyMSPerMB
option accepts integer values representing milliseconds per one megabyte of the current heap size (for Java HotSpot Client VM) or the maximum possible heap size (for Java HotSpot Server VM). This difference means that the Client VM tends to flush soft references rather than grow the heap, whereas the Server VM tends to grow the heap rather than flush soft references. In the latter case, the value of the-Xmx
option has a significant effect on how quickly soft references are garbage collected.The following example shows how to set the value to 2.5 seconds:
-XX:SoftRefLRUPolicyMSPerMB=2500
-XX:-ShrinkHeapInSteps
-
Incrementally reduces the Java heap to the target size, specified by the option
-XX:MaxHeapFreeRatio
. This option is enabled by default. If disabled, then it immediately reduces the Java heap to the target size instead of requiring multiple garbage collection cycles. Disable this option if you want to minimize the Java heap size. You will likely encounter performance degradation when this option is disabled.See Performance Tuning Examples for a description of using the
MaxHeapFreeRatio
option to keep the Java heap small by reducing the dynamic footprint for embedded applications. -XX:StringDeduplicationAgeThreshold=
threshold-
Identifies
String
objects reaching the specified age that are considered candidates for deduplication. An object's age is a measure of how many times it has survived garbage collection. This is sometimes referred to as tenuring.Note:
String
objects that are promoted to an old heap region before this age has been reached are always considered candidates for deduplication. The default value for this option is3
. See the-XX:+UseStringDeduplication
option. -XX:SurvivorRatio=
ratio-
Sets the ratio between eden space size and survivor space size. By default, this option is set to 8. The following example shows how to set the eden/survivor space ratio to 4:
-XX:SurvivorRatio=4
-XX:TargetSurvivorRatio=
percent-
Sets the desired percentage of survivor space (0 to 100) used after young garbage collection. By default, this option is set to 50%.
The following example shows how to set the target survivor space ratio to 30%:
-XX:TargetSurvivorRatio=30
-XX:TLABSize=
size-
Sets the initial size (in bytes) of a thread-local allocation buffer (TLAB). Append the letter
k
orK
to indicate kilobytes,m
orM
to indicate megabytes, org
orG
to indicate gigabytes. If this option is set to 0, then the JVM selects the initial size automatically.The following example shows how to set the initial TLAB size to 512 KB:
-XX:TLABSize=512k
-XX:+UseAdaptiveSizePolicy
-
Enables the use of adaptive generation sizing. This option is enabled by
default. To disable adaptive generation sizing, specify
-XX:-UseAdaptiveSizePolicy
and set the size of the memory allocation pool explicitly. See the-XX:SurvivorRatio
option. -XX:+UseG1GC
- Enables the use of the garbage-first (G1) garbage collector. It's a server-style garbage collector, targeted for multiprocessor machines with a large amount of RAM. This option meets GC pause time goals with high probability, while maintaining good throughput. The G1 collector is recommended for applications requiring large heaps (sizes of around 6 GB or larger) with limited GC latency requirements (a stable and predictable pause time below 0.5 seconds). By default, this option is enabled and G1 is used as the default garbage collector.
-XX:+UseGCOverheadLimit
-
Enables the use of a policy that limits the proportion of time spent by
the JVM on GC before an
OutOfMemoryError
exception is thrown. This option is enabled, by default, and the parallel GC will throw anOutOfMemoryError
if more than 98% of the total time is spent on garbage collection and less than 2% of the heap is recovered. When the heap is small, this feature can be used to prevent applications from running for long periods of time with little or no progress. To disable this option, specify the option-XX:-UseGCOverheadLimit
. -XX:+UseNUMA
-
Enables performance optimization of an application on a machine with
nonuniform memory architecture (NUMA) by increasing the application's
use of lower latency memory. By default, this option is disabled and no
optimization for NUMA is made. The option is available only when the
parallel garbage collector is used (
-XX:+UseParallelGC
). -XX:+UseParallelGC
-
Enables the use of the parallel scavenge garbage collector (also known as the throughput collector) to improve the performance of your application by leveraging multiple processors.
By default, this option is disabled and the default collector is used.
-XX:+UseSerialGC
- Enables the use of the serial garbage collector. This is generally the best choice for small and simple applications that don't require any special functionality from garbage collection. By default, this option is disabled and the default collector is used.
-XX:+UseStringDeduplication
-
Enables string deduplication. By default, this option is disabled. To use this option, you must enable the garbage-first (G1) garbage collector.
String deduplication reduces the memory footprint of
String
objects on the Java heap by taking advantage of the fact that manyString
objects are identical. Instead of eachString
object pointing to its own character array, identicalString
objects can point to and share the same character array. -XX:+UseTLAB
-
Enables the use of thread-local allocation blocks (TLABs) in the young
generation space. This option is enabled by default. To disable the use
of TLABs, specify the option
-XX:-UseTLAB
. -XX:+UseZGC
- Enables the use of the Z garbage collector (ZGC). This is a low latency garbage collector, providing max pause times of a few milliseconds, at some throughput cost. Pause times are independent of what heap size is used. Supports heap sizes from 8MB to 16TB.
-XX:ZAllocationSpikeTolerance=
factor- Sets the allocation spike tolerance for ZGC. By default, this option is set to 2.0. This factor describes the level of allocation spikes to expect. For example, using a factor of 3.0 means the current allocation rate can be expected to triple at any time.
-XX:ZCollectionInterval=
seconds- Sets the maximum interval (in seconds) between two GC cycles when using ZGC. By default, this option is set to 0 (disabled).
-XX:ZFragmentationLimit=
percent- Sets the maximum acceptable heap fragmentation (in percent) for ZGC. By default, this option is set to 25. Using a lower value will cause the heap to be compacted more aggressively, to reclaim more memory at the cost of using more CPU time.
-XX:+ZProactive
- Enables proactive GC cycles when using ZGC. By default, this option is enabled. ZGC will start a proactive GC cycle if doing so is expected to have minimal impact on the running application. This is useful if the application is mostly idle or allocates very few objects, but you still want to keep the heap size down and allow reference processing to happen even when there are a lot of free space on the heap.
-XX:+ZUncommit
- Enables uncommitting of unused heap memory when using ZGC. By default, this option is enabled. Uncommitting unused heap memory will lower the memory footprint of the JVM, and make that memory available for other processes to use.
-XX:ZUncommitDelay=
seconds- Sets the amount of time (in seconds) that heap memory must have been unused before being uncommitted. By default, this option is set to 300 (5 minutes). Committing and uncommitting memory are relatively expensive operations. Using a lower value will cause heap memory to be uncommitted earlier, at the risk of soon having to commit it again.
Deprecated Java Options
These java
options are deprecated and might be removed
in a future JDK release. They're still accepted and acted upon, but a
warning is issued when they're used.
-Xloggc:
filename-
Sets the file to which verbose GC events information should be redirected for logging. The
-Xloggc
option overrides-verbose:gc
if both are given with the same java command.-Xloggc:
filename is replaced by-Xlog:gc:
filename. See Enable Logging with the JVM Unified Logging Framework.Example:
-Xlog:gc:garbage-collection.log
-XX:+FlightRecorder
- Enables the use of Java Flight Recorder (JFR) during the runtime of the application. Since JDK 8u40 this option has not been required to use JFR.
Obsolete Java Options
These java
options are still accepted but ignored, and a
warning is issued when they're used.
--illegal-access=
parameter- Controlled relaxed strong encapsulation, as defined in JEP 261. This option was deprecated in JDK 16 by JEP 396 and made obsolete in JDK 17 by JEP 403.
-XX:RTMAbortRatio=
abort_ratio-
Specifies the RTM abort ratio is specified as a percentage (%) of all executed RTM transactions. If a number of aborted transactions becomes greater than this ratio, then the compiled code is deoptimized. This ratio is used when the
-XX:+UseRTMDeopt
option is enabled. The default value of this option is 50. This means that the compiled code is deoptimized if 50% of all transactions are aborted.The
-XX:RTMAbortRatio
option is not applicable to the Graal JIT compiler because Graal does not support generating RTM locking code for all inflated locks. If you have enabled the Graal JIT compiler, this option is ignored. (See Enabling the Graal JIT Compiler for a description of how to enable and disable the Graal JIT compiler.) -XX:RTMRetryCount=
number_of_retries-
Specifies the number of times that the RTM locking code is retried, when it is aborted or busy, before falling back to the normal locking mechanism. The default value for this option is 5. The
-XX:UseRTMLocking
option must be enabled.The
-XX:RTMRetryCount
option is not applicable to the Graal JIT compiler because Graal does not support generating RTM locking code for all inflated locks. If you have enabled the Graal JIT compiler, this option is ignored. (See Enabling the Graal JIT Compiler for a description of how to enable and disable the Graal JIT compiler.) -XX:+UseRTMDeopt
-
Autotunes RTM locking depending on the abort ratio. This ratio is specified by the
-XX:RTMAbortRatio
option. If the number of aborted transactions exceeds the abort ratio, then the method containing the lock is deoptimized and recompiled with all locks as normal locks. This option is disabled by default. The-XX:+UseRTMLocking
option must be enabled.The
-XX:+UseRTMDeopt
option is not applicable to the Graal JIT compiler because the Graal JIT compiler does not support generating RTM locking code for all inflated locks. If you have enabled the Graal JIT compiler, this option is ignored. (See Enabling the Graal JIT Compiler for a description of how to enable and disable the Graal JIT compiler.) -XX:+UseRTMLocking
-
Generates Restricted Transactional Memory (RTM) locking code for all inflated locks, with the normal locking mechanism as the fallback handler. This option is disabled by default. Options related to RTM are available only on x86 CPUs that support Transactional Synchronization Extensions (TSX).
RTM is part of Intel's TSX, which is an x86 instruction set extension and facilitates the creation of multithreaded applications. RTM introduces the new instructions
XBEGIN
,XABORT
,XEND
, andXTEST
. TheXBEGIN
andXEND
instructions enclose a set of instructions to run as a transaction. If no conflict is found when running the transaction, then the memory and register modifications are committed together at theXEND
instruction. TheXABORT
instruction can be used to explicitly abort a transaction and theXTEST
instruction checks if a set of instructions is being run in a transaction.A lock on a transaction is inflated when another thread tries to access the same transaction, thereby blocking the thread that didn't originally request access to the transaction. RTM requires that a fallback set of operations be specified in case a transaction aborts or fails. An RTM lock is a lock that has been delegated to the TSX's system.
RTM improves performance for highly contended locks with low conflict in a critical region (which is code that must not be accessed by more than one thread concurrently). RTM also improves the performance of coarse-grain locking, which typically doesn't perform well in multithreaded applications. (Coarse-grain locking is the strategy of holding locks for long periods to minimize the overhead of taking and releasing locks, while fine-grained locking is the strategy of trying to achieve maximum parallelism by locking only when necessary and unlocking as soon as possible.) Also, for lightly contended locks that are used by different threads, RTM can reduce false cache line sharing, also known as cache line ping-pong. This occurs when multiple threads from different processors are accessing different resources, but the resources share the same cache line. As a result, the processors repeatedly invalidate the cache lines of other processors, which forces them to read from main memory instead of their cache.
The
-XX:+UseRTMLocking
option is not applicable to the Graal JIT compiler because the Graal JIT compiler does not support generating RTM locking code for all inflated locks. If you have enabled the Graal JIT compiler, this option is ignored. (See Enabling the Graal JIT Compiler for a description of how to enable and disable the Graal JIT compiler.)
Removed Java Options
These java
options have been removed in JDK 25 and using
them results in an error of:
Unrecognized VM option
option-name
-XX:InitialRAMFraction=
ratio-
Sets the initial amount of memory that the JVM may use for the Java heap before applying ergonomics heuristics as a ratio of the maximum amount determined as described in the
-XX:MaxRAM
option. The default value is 64.Use the option
-XX:InitialRAMPercentage
instead. -XX:MaxRAMFraction=
ratio-
Sets the maximum amount of memory that the JVM may use for the Java heap before applying ergonomics heuristics as a fraction of the maximum amount determined as described in the
-XX:MaxRAM
option. The default value is 4.Specifying this option disables automatic use of compressed oops if the combined result of this and other options influencing the maximum amount of memory is larger than the range of memory addressable by compressed oops. See
-XX:UseCompressedOops
for further information about compressed oops.Use the option
-XX:MaxRAMPercentage
instead. -XX:MinRAMFraction=
ratio-
Sets the maximum amount of memory that the JVM may use for the Java heap before applying ergonomics heuristics as a fraction of the maximum amount determined as described in the
-XX:MaxRAM
option for small heaps. A small heap is a heap of approximately 125 MB. The default value is 2.Use the option
-XX:MinRAMPercentage
instead. -XX:+ScavengeBeforeFullGC
-
Enables GC of the young generation before each full GC. This option is
enabled by default. It is recommended that you don't disable
it, because scavenging the young generation before a full GC can reduce
the number of objects reachable from the old generation space into the
young generation space. To disable GC of the young generation before
each full GC, specify the option
-XX:-ScavengeBeforeFullGC
. -Xfuture
-
Enables strict class-file format checks that enforce close conformance to the class-file format specification. Developers should use this flag when developing new code. Stricter checks may become the default in future releases.
Use the option
-Xverify:all
instead.
For the lists and descriptions of options removed in previous releases see the Removed Java Options section in:
java Command-Line Argument Files
You can shorten or simplify the java
command by using
@
argument files to specify one or more text files that
contain arguments, such as options and class names, which are passed to
the java
command. This let's you to create
java
commands of any length on any operating system.
In the command line, use the at sign (@
) prefix to
identify an argument file that contains java
options and
class names. When the java
command encounters a file
beginning with the at sign (@
), it expands the contents of
that file into an argument list just as they would be specified on the
command line.
The java
launcher expands the argument file contents
until it encounters the --disable-@files
option. You can
use the --disable-@files
option anywhere on the command
line, including in an argument file, to stop @
argument
files expansion.
The following items describe the syntax of java
argument
files:
The argument file must contain only ASCII characters or characters in system default encoding that's ASCII friendly, such as UTF-8.
The argument file size must not exceed MAXINT (2,147,483,647) bytes.
The launcher doesn't expand wildcards that are present within an argument file.
Use white space or new line characters to separate arguments included in the file.
White space includes a white space character,
\t
,\n
,\r
, and\f
.For example, it is possible to have a path with a space, such as
c:\Program Files
that can be specified as either"c:\\Program Files"
or, to avoid an escape,c:\Program" "Files
.Any option that contains spaces, such as a path component, must be within quotation marks using quotation ('"') characters in its entirety.
A string within quotation marks may contain the characters
\n
,\r
,\t
, and\f
. They are converted to their respective ASCII codes.If a file name contains embedded spaces, then put the whole file name in double quotation marks.
File names in an argument file are relative to the current directory, not to the location of the argument file.
Use the number sign
#
in the argument file to identify comments. All characters following the#
are ignored until the end of line.Additional at sign
@
prefixes to@
prefixed options act as an escape, (the first@
is removed and the rest of the arguments are presented to the launcher literally).Lines may be continued using the continuation character (
\
) at the end-of-line. The two lines are concatenated with the leading white spaces trimmed. To prevent trimming the leading white spaces, a continuation character (\
) may be placed at the first column.Because backslash (\) is an escape character, a backslash character must be escaped with another backslash character.
Partial quote is allowed and is closed by an end-of-file.
An open quote stops at end-of-line unless
\
is the last character, which then joins the next line by removing all leading white space characters.Wildcards (*) aren't allowed in these lists (such as specifying
*.java
).Use of the at sign (
@
) to recursively interpret files isn't supported.
Example of Open or Partial Quotes in an Argument File
In the argument file,
-cp "lib/
cool/
app/
jars
this is interpreted as:
-cp lib/cool/app/jars
Example of a Backslash Character Escaped with Another Backslash Character in an Argument File
To output the following:
-cp c:\Program Files (x86)\Java\jre\lib\ext;c:\Program Files\Java\jre9\lib\ext
The backslash character must be specified in the argument file as:
-cp "c:\\Program Files (x86)\\Java\\jre\\lib\\ext;c:\\Program Files\\Java\\jre9\\lib\\ext"
Example of an EOL Escape Used to Force Concatenation of Lines in an Argument File
In the argument file,
-cp "/lib/cool app/jars:\
/lib/another app/jars"
This is interpreted as:
-cp /lib/cool app/jars:/lib/another app/jars
Example of Line Continuation with Leading Spaces in an Argument File
In the argument file,
-cp "/lib/cool\
\app/jars"
This is interpreted as:
-cp /lib/cool app/jars
Examples of Using Single Argument File
You can use a single argument file, such as
myargumentfile
in the following example, to hold all
required java
arguments:
java @myargumentfile
Examples of Using Argument Files with Paths
You can include relative paths in argument files; however, they're
relative to the current working directory and not to the paths of the
argument files themselves. In the following example,
path1/options
and path2/options
represent
argument files with different paths. Any relative paths that they
contain are relative to the current working directory and not to the
argument files:
java @path1/options @path2/classes
Code Heap State Analytics
Overview
There are occasions when having insight into the current state of the JVM code heap would be helpful to answer questions such as:
Why was the JIT turned off and then on again and again?
Where has all the code heap space gone?
Why is the method sweeper not working effectively?
To provide this insight, a code heap state analytics feature has been implemented that enables on-the-fly analysis of the code heap. The analytics process is divided into two parts. The first part examines the entire code heap and aggregates all information that is believed to be useful or important. The second part consists of several independent steps that print the collected information with an emphasis on different aspects of the data. Data collection and printing are done on an "on request" basis.
Syntax
Requests for real-time, on-the-fly analysis can be issued with the following command:
jcmd
pidCompiler.CodeHeap_Analytics
[function] [granularity]
If you are only interested in how the code heap looks like after running a sample workload, you can use the command line option:
-Xlog:codecache=Trace
To see the code heap state when a "CodeCache full" condition exists, start the VM with the command line option:
-Xlog:codecache=Debug
See CodeHeap State Analytics (OpenJDK) for a detailed description of the code heap state analytics feature, the supported functions, and the granularity options.
Enable Logging with the JVM Unified Logging Framework
You use the -Xlog
option to configure or enable logging
with the Java Virtual Machine (JVM) unified logging framework.
Synopsis
-Xlog
[:
[what][:
[output][:
[decorators][:
output-options[,
...]]]]]
-Xlog:
directive
- what
-
Specifies a combination of tags and levels of the form
tag1[
+
tag2...][*
][=
level][,
...]. Unless the wildcard (*
) is specified, only log messages tagged with exactly the tags specified are matched. See -Xlog Tags and Levels. - output
-
Sets the type of output. Omitting the output type defaults to
stdout
. See -Xlog Output. - decorators
-
Configures the output to use a custom set of decorators. Omitting
decorators defaults to
uptime
,level
, andtags
. See Decorations. - output-options
-
Sets the
-Xlog
logging output options. - directive
- A global option or subcommand: help, disable, async
Description
The Java Virtual Machine (JVM) unified logging framework provides a common logging system for all components of the JVM. GC logging for the JVM has been changed to use the new logging framework. The mapping of old GC flags to the corresponding new Xlog configuration is described in Convert GC Logging Flags to Xlog. In addition, runtime logging has also been changed to use the JVM unified logging framework. The mapping of legacy runtime logging flags to the corresponding new Xlog configuration is described in Convert Runtime Logging Flags to Xlog.
The following provides quick reference to the -Xlog
command and syntax for options:
-Xlog
-
Enables JVM logging on an
info
level. -Xlog:help
-
Prints
-Xlog
usage syntax and available tags, levels, and decorators along with example command lines with explanations. -Xlog:disable
- Turns off all logging and clears all configuration of the logging framework including the default configuration for warnings and errors.
-Xlog
[:
option]-
Applies multiple arguments in the order that they appear on the command line. Multiple
-Xlog
arguments for the same output override each other in their given order.The option is set as:
[tag-selection][
:
[output][:
[decorators][:
output-options]]]Omitting the tag-selection defaults to a tag-set of
all
and a level ofinfo
.tag[
+
...]all
The
all
tag is a meta tag consisting of all tag-sets available. The asterisk*
in a tag set definition denotes a wildcard tag match. Matching with a wildcard selects all tag sets that contain at least the specified tags. Without the wildcard, only exact matches of the specified tag sets are selected.output-options is
filecount=
file-countfilesize=
file size with optional K, M or G suffixfoldmultilines=
<true|false>When
foldmultilines
is true, a log event that consists of multiple lines will be folded into a single line by replacing newline characters with the sequence'\'
and'n'
in the output. Existing single backslash characters will also be replaced with a sequence of two backslashes so that the conversion can be reversed. This option is safe to use with UTF-8 character encodings, but other encodings may not work. For example, it may incorrectly convert multi-byte sequences in Shift JIS and BIG5.
Default Configuration
When the -Xlog
option and nothing else is specified on
the command line, the default configuration is used. The default
configuration logs all messages with a level that matches either warning
or error regardless of what tags the message is associated with. The
default configuration is equivalent to entering the following on the
command line:
-Xlog:all=warning:stdout:uptime,level,tags
Controlling Logging at Runtime
Logging can also be controlled at run time through Diagnostic
Commands (with the jcmd utility). Everything
that can be specified on the command line can also be specified
dynamically with the VM.log
command. As the diagnostic
commands are automatically exposed as MBeans, you can use JMX to change
logging configuration at run time.
-Xlog Tags and Levels
Each log message has a level and a tag set associated with it. The
level of the message corresponds to its details, and the tag set
corresponds to what the message contains or which JVM component it
involves (such as, gc
, jit
, or
os
). Mapping GC flags to the Xlog configuration is
described in Convert GC
Logging Flags to Xlog. Mapping legacy runtime logging flags to the
corresponding Xlog configuration is described in Convert Runtime Logging
Flags to Xlog.
Available log levels:
off
trace
debug
info
warning
error
Available log tags:
There are literally dozens of log tags, which in the right
combinations, will enable a range of logging output. The full set of
available log tags can be seen using -Xlog:help
. Specifying
all
instead of a tag combination matches all tag
combinations.
-Xlog Output
The -Xlog
option supports the following types of
outputs:
stdout
--- Sends output to stdoutstderr
--- Sends output to stderrfile=
filename --- Sends output to text file(s).
When using file=
filename, specifying
%p
, %t
and/or %hn
in the file
name expands to the JVM's PID, startup timestamp and host name,
respectively. You can also configure text files to handle file rotation
based on file size and a number of files to rotate. For example, to
rotate the log file every 10 MB and keep 5 files in rotation, specify
the options filesize=10M, filecount=5
. The target size of
the files isn't guaranteed to be exact, it's just an approximate value.
Files are rotated by default with up to 5 rotated files of target size
20 MB, unless configured otherwise. Specifying filecount=0
means that the log file shouldn't be rotated. There's a possibility of
the pre-existing log file getting overwritten.
-Xlog Output Mode
By default logging messages are output synchronously - each log message is written to the designated output when the logging call is made. But you can instead use asynchronous logging mode by specifying:
-Xlog:async
- Write all logging asynchronously.
In asynchronous logging mode, log sites enqueue all logging messages to an intermediate buffer and a standalone thread is responsible for flushing them to the corresponding outputs. The intermediate buffer is bounded and on buffer exhaustion the enqueuing message is discarded. Log entry write operations are guaranteed non-blocking.
The option -XX:AsyncLogBufferSize=N
specifies the memory
budget in bytes for the intermediate buffer. The default value should be
big enough to cater for most cases. Users can provide a custom value to
trade memory overhead for log accuracy if they need to.
Decorations
Logging messages are decorated with information about the message. You can configure each output to use a custom set of decorators. The order of the output is always the same as listed in the table. You can configure the decorations to be used at run time. Decorations are prepended to the log message. For example:
[6.567s][info][gc,old] Old collection complete
Omitting decorators
defaults to uptime
,
level
, and tags
. The none
decorator is special and is used to turn off all decorations.
time
(t
), utctime
(utc
), uptime
(u
),
timemillis
(tm
), uptimemillis
(um
), timenanos
(tn
),
uptimenanos
(un
), hostname
(hn
), pid
(p
), tid
(ti
), level
(l
),
tags
(tg
) decorators can also be specified as
none
for no decoration.
Decorations | Description |
---|---|
time or t |
Current time and date in ISO-8601 format. |
utctime or
utc |
Universal Time Coordinated or Coordinated Universal Time. |
uptime or u |
Time since the start of the JVM in seconds and milliseconds. For example, 6.567s. |
timemillis or
tm |
The same value as generated by
System.currentTimeMillis() |
uptimemillis or
um |
Milliseconds since the JVM started. |
timenanos or
tn |
The same value generated by
System.nanoTime() . |
uptimenanos or
un |
Nanoseconds since the JVM started. |
hostname or
hn |
The host name. |
pid or p |
The process identifier. |
tid or ti |
The thread identifier. |
level or l |
The level associated with the log message. |
tags or tg |
The tag-set associated with the log message. |
Convert GC Logging Flags to Xlog
Legacy Garbage Collection (GC) Flag | Xlog Configuration | Comment |
---|---|---|
G1PrintHeapRegions |
-Xlog:gc+region=trace |
Not Applicable |
GCLogFileSize |
No configuration available | Log rotation is handled by the framework. |
NumberOfGCLogFiles |
Not Applicable | Log rotation is handled by the framework. |
PrintAdaptiveSizePolicy |
-Xlog:gc+ergo*= level |
Use a level of debug
for most of the information, or a level of trace
for all of what was logged for
PrintAdaptiveSizePolicy . |
PrintGC |
-Xlog:gc |
Not Applicable |
PrintGCApplicationConcurrentTime |
-Xlog:safepoint |
Note that
PrintGCApplicationConcurrentTime and
PrintGCApplicationStoppedTime are logged on the same tag
and aren't separated in the new logging. |
PrintGCApplicationStoppedTime |
-Xlog:safepoint |
Note that
PrintGCApplicationConcurrentTime and
PrintGCApplicationStoppedTime are logged on the same tag
and not separated in the new logging. |
PrintGCCause |
Not Applicable | GC cause is now always logged. |
PrintGCDateStamps |
Not Applicable | Date stamps are logged by the framework. |
PrintGCDetails |
-Xlog:gc* |
Not Applicable |
PrintGCID |
Not Applicable | GC ID is now always logged. |
PrintGCTaskTimeStamps |
-Xlog:gc+task*=debug |
Not Applicable |
PrintGCTimeStamps |
Not Applicable | Time stamps are logged by the framework. |
PrintHeapAtGC |
-Xlog:gc+heap=trace |
Not Applicable |
PrintReferenceGC |
-Xlog:gc+ref*=debug |
Note that in the old logging,
PrintReferenceGC had an effect only if
PrintGCDetails was also enabled. |
PrintStringDeduplicationStatistics |
`-Xlog:gc+stringdedup*=debug | ` Not Applicable |
PrintTenuringDistribution |
-Xlog:gc+age*= level |
Use a level of debug
for the most relevant information, or a level of
trace for all of what was logged for
PrintTenuringDistribution . |
UseGCLogFileRotation |
Not Applicable | What was logged for
PrintTenuringDistribution . |
Convert Runtime Logging Flags to Xlog
These legacy flags are no longer recognized and will cause an error if used directly. Use their unified logging equivalent instead.
Legacy Runtime Flag | Xlog Configuration | Comment |
---|---|---|
TraceExceptions |
-Xlog:exceptions=info |
Not Applicable |
TraceClassLoading |
-Xlog:class+load= level |
Use level=info for
regular information, or level=debug for additional
information. In Unified Logging syntax, -verbose:class
equals -Xlog:class+load=info,class+unload=info . |
TraceClassLoadingPreorder |
-Xlog:class+preorder=debug |
Not Applicable |
TraceClassUnloading |
-Xlog:class+unload= level |
Use level=info for
regular information, or level=trace for additional
information. In Unified Logging syntax, -verbose:class
equals -Xlog:class+load=info,class+unload=info . |
VerboseVerification |
-Xlog:verification=info |
Not Applicable |
TraceClassPaths |
-Xlog:class+path=info |
Not Applicable |
TraceClassResolution |
-Xlog:class+resolve=debug |
Not Applicable |
TraceClassInitialization |
-Xlog:class+init=info |
Not Applicable |
TraceLoaderConstraints |
-Xlog:class+loader+constraints=info |
Not Applicable |
TraceClassLoaderData |
-Xlog:class+loader+data= level |
Use level=debug for
regular information or level=trace for additional
information. |
TraceSafepointCleanupTime |
-Xlog:safepoint+cleanup=info |
Not Applicable |
TraceSafepoint |
-Xlog:safepoint=debug |
Not Applicable |
TraceMonitorInflation |
-Xlog:monitorinflation=debug |
Not Applicable |
TraceRedefineClasses |
-Xlog:redefine+class*= level |
level=info ,
debug , and trace provide increasing amounts of
information. |
-Xlog Usage Examples
The following are -Xlog
examples.
-Xlog
-
Logs all messages by using the
info
level tostdout
withuptime
,levels
, andtags
decorations. This is equivalent to using:-Xlog:all=info:stdout:uptime,levels,tags
-Xlog:gc
-
Logs messages tagged with the
gc
tag usinginfo
level tostdout
. The default configuration for all other messages at levelwarning
is in effect. -Xlog:gc,safepoint
-
Logs messages tagged either with the
gc
orsafepoint
tags, both using theinfo
level, tostdout
, with default decorations. Messages tagged with bothgc
andsafepoint
won't be logged. -Xlog:gc+ref=debug
-
Logs messages tagged with both
gc
andref
tags, using thedebug
level tostdout
, with default decorations. Messages tagged only with one of the two tags won't be logged. -Xlog:gc=debug:file=gc.txt:none
-
Logs messages tagged with the
gc
tag using thedebug
level to a file calledgc.txt
with no decorations. The default configuration for all other messages at levelwarning
is still in effect. -Xlog:gc=trace:file=gctrace.txt:uptimemillis,pids:filecount=5,filesize=1024
-
Logs messages tagged with the
gc
tag using thetrace
level to a rotating file set with 5 files with size 1 MB with the base namegctrace.txt
and uses decorationsuptimemillis
andpid
.The default configuration for all other messages at level
warning
is still in effect. -Xlog:gc::uptime,tid
-
Logs messages tagged with the
gc
tag using the default 'info' level to default the outputstdout
and uses decorationsuptime
andtid
. The default configuration for all other messages at levelwarning
is still in effect. -Xlog:gc*=info,safepoint*=off
-
Logs messages tagged with at least
gc
using theinfo
level, but turns off logging of messages tagged withsafepoint
. Messages tagged with bothgc
andsafepoint
won't be logged. -Xlog:disable -Xlog:safepoint=trace:safepointtrace.txt
-
Turns off all logging, including warnings and errors, and then enables
messages tagged with
safepoint
usingtrace
level to the filesafepointtrace.txt
. The default configuration doesn't apply, because the command line started with-Xlog:disable
.
Complex -Xlog Usage Examples
The following describes a few complex examples of using the
-Xlog
option.
-Xlog:gc+class*=debug
-
Logs messages tagged with at least
gc
andclass
tags using thedebug
level tostdout
. The default configuration for all other messages at the levelwarning
is still in effect -Xlog:gc+meta*=trace,class*=off:file=gcmetatrace.txt
-
Logs messages tagged with at least the
gc
andmeta
tags using thetrace
level to the filemetatrace.txt
but turns off all messages tagged withclass
. Messages tagged withgc
,meta
, andclass
aren't be logged asclass*
is set to off. The default configuration for all other messages at levelwarning
is in effect except for those that includeclass
. -Xlog:gc+meta=trace
-
Logs messages tagged with exactly the
gc
andmeta
tags using thetrace
level tostdout
. The default configuration for all other messages at levelwarning
is still be in effect. -Xlog:gc+class+heap*=debug,meta*=warning,threads*=off
-
Logs messages tagged with at least
gc
,class
, andheap
tags using thetrace
level tostdout
but only log messages tagged withmeta
with level. The default configuration for all other messages at the levelwarning
is in effect except for those that includethreads
.
Validate Java Virtual Machine Flag Arguments
You use values provided to all Java Virtual Machine (JVM) command-line flags for validation and, if the input value is invalid or out-of-range, then an appropriate error message is displayed.
Whether they're set ergonomically, in a command line, by an input
tool, or through the APIs (for example, classes contained in the package
java.lang.management
) the values provided to all Java
Virtual Machine (JVM) command-line flags are validated. Ergonomics are
described in Java Platform, Standard Edition HotSpot Virtual Machine
Garbage Collection Tuning Guide.
Range and constraints are validated either when all flags have their
values set during JVM initialization or a flag's value is changed during
runtime (for example using the jcmd
tool). The JVM is
terminated if a value violates either the range or constraint check and
an appropriate error message is printed on the error stream.
For example, if a flag violates a range or a constraint check, then the JVM exits with an error:
java -XX:AllocatePrefetchStyle=5 -version
intx AllocatePrefetchStyle=5 is outside the allowed range [ 0 ... 3 ]
Improperly specified VM option 'AllocatePrefetchStyle=5'
Error: Could not create the Java Virtual Machine.
Error: A fatal exception has occurred. Program will exit.
The flag -XX:+PrintFlagsRanges
prints the range of all
the flags. This flag allows automatic testing of the flags by the values
provided by the ranges. For the flags that have the ranges specified,
the type, name, and the actual range is printed in the output.
For example,
intx ThreadStackSize [ 0 ... 9007199254740987 ] {pd product}
For the flags that don't have the range specified, the values aren't displayed in the print out. For example:
size_t NewSize [ ... ] {product}
This helps to identify the flags that need to be implemented. The automatic testing framework can skip those flags that don't have values and aren't implemented.
Large Pages
You use large pages, also known as huge pages, as memory pages that are significantly larger than the standard memory page size (which varies depending on the processor and operating system). Large pages optimize processor Translation-Lookaside Buffers.
A Translation-Lookaside Buffer (TLB) is a page translation cache that holds the most-recently used virtual-to-physical address translations. A TLB is a scarce system resource. A TLB miss can be costly because the processor must then read from the hierarchical page table, which may require multiple memory accesses. By using a larger memory page size, a single TLB entry can represent a larger memory range. This results in less pressure on a TLB, and memory-intensive applications may have better performance.
However, using large pages can negatively affect system performance. For example, when a large amount of memory is pinned by an application, it may create a shortage of regular memory and cause excessive paging in other applications and slow down the entire system. Also, a system that has been up for a long time could produce excessive fragmentation, which could make it impossible to reserve enough large page memory. When this happens, either the OS or JVM reverts to using regular pages.
Linux and Windows support large pages.
Large Pages Support for Linux
Linux supports large pages since version 2.6. To check if your environment supports large pages, try the following:
# cat /proc/meminfo | grep Huge
HugePages_Total: 0
HugePages_Free: 0
...
Hugepagesize: 2048 kB
If the output contains items prefixed with "Huge", then your system
supports large pages. The values may vary depending on environment. The
Hugepagesize
field shows the default large page size in
your environment, and the other fields show details for large pages of
this size. Newer kernels have support for multiple large page sizes. To
list the supported page sizes, run this:
# ls /sys/kernel/mm/hugepages/
hugepages-1048576kB hugepages-2048kB
The above environment supports 2 MB and 1 GB large pages, but they
need to be configured so that the JVM can use them. When using large
pages and not enabling transparent huge pages (option
-XX:+UseTransparentHugePages
), the number of large pages
must be pre-allocated. For example, to enable 8 GB of memory to be
backed by 2 MB large pages, login as root
and run:
# echo 4096 > /sys/kernel/mm/hugepages/hugepages-2048kB/nr_hugepages
It is always recommended to check the value of
nr_hugepages
after the request to make sure the kernel was
able to allocate the requested number of large pages.
Note: The values contained in
/proc
and/sys
reset after you reboot your system, so may want to set them in an initialization script (for example,rc.local
orsysctl.conf
).
If you configure the OS kernel parameters to enable use of large pages, the Java processes may allocate large pages for the Java heap as well as other internal areas, for example:
- Code cache
- Marking bitmaps
Consequently, if you configure the nr_hugepages
parameter to the size of the Java heap, then the JVM can still fail to
allocate the heap using large pages because other areas such as the code
cache might already have used some of the configured large pages.
Large Pages Support for Windows
To use large pages support on Windows, the administrator must first assign additional privileges to the user who is running the application:
- Select Control Panel, Administrative Tools, and then Local Security Policy.
- Select Local Policies and then User Rights Assignment.
- Double-click Lock pages in memory, then add users and/or groups.
- Reboot your system.
Note that these steps are required even if it's the administrator who's running the application, because administrators by default don't have the privilege to lock pages in memory.
Application Class Data Sharing
Application Class Data Sharing (AppCDS) stores classes used by your applications in an archive file. Since these classes are stored in a format that can be loaded very quickly (compared to classes stored in a JAR file), AppCDS can improve the start-up time of your applications. In addition, AppCDS can reduce the runtime memory footprint by sharing parts of these classes across multiple processes.
Classes in the CDS archive are stored in an optimized format that's about 2 to 5 times larger than classes stored in JAR files or the JDK runtime image. Therefore, it's a good idea to archive only those classes that are actually used by your application. These usually are just a small portion of all available classes. For example, your application may use only a few APIs provided by a large library.
Using CDS Archives
By default, in most JDK distributions, unless
-Xshare:off
is specified, the JVM starts up with a default
CDS archive, which is usually located in
JAVA_HOME/lib/server/classes.jsa
(or
JAVA_HOME\bin\server\classes.jsa
on Windows). This archive
contains about 1300 core library classes that are used by most
applications.
To use CDS for the exact set of classes used by your application, you
can use the -XX:SharedArchiveFile
option, which has the
general form:
-XX:SharedArchiveFile=<static_archive>:<dynamic_archive>
- The
<static_archive>
overrides the default CDS archive. - The
<dynamic_archive>
provides additional classes that can be loaded on top of those in the<static_archive>
. - On Windows, the above path delimiter
:
should be replaced with;
(The names "static" and "dynamic" are used for historical reasons. The only significance is that the "static" archive is loaded first and the "dynamic" archive is loaded second).
The JVM can use up to two archives. To use only a single
<static_archive>
, you can omit the
<dynamic_archive>
portion:
-XX:SharedArchiveFile=<static_archive>
For convenience, the <dynamic_archive>
records the
location of the <static_archive>
. Therefore, you can
omit the <static_archive>
by saying only:
-XX:SharedArchiveFile=<dynamic_archive>
Manually Creating CDS Archives
CDS archives can be created manually using several methods:
-Xshare:dump
-XX:ArchiveClassesAtExit
jcmd VM.cds
One common operation in all these methods is a "trial run", where you run the application once to determine the classes that should be stored in the archive.
Creating a Static CDS Archive File with -Xshare:dump
The following steps create a static CDS archive file that contains
all the classes used by the test.Hello
application.
Create a list of all classes used by the
test.Hello
application. The following command creates a file namedhello.classlist
that contains a list of all classes used by this application:java -Xshare:off -XX:DumpLoadedClassList=hello.classlist -cp hello.jar test.Hello
The classpath specified by the
-cp
parameter must contain only JAR files.Create a static archive, named
hello.jsa
, that contains all the classes inhello.classlist
:java -Xshare:dump -XX:SharedArchiveFile=hello.jsa -XX:SharedClassListFile=hello.classlist -cp hello.jar
Run the application
test.Hello
with the archivehello.jsa
:java -XX:SharedArchiveFile=hello.jsa -cp hello.jar test.Hello
Optional Verify that the
test.Hello
application is using the class contained in thehello.jsa
shared archive:java -XX:SharedArchiveFile=hello.jsa -cp hello.jar -Xlog:class+load test.Hello
The output of this command should contain the following text:
[info][class,load] test.Hello source: shared objects file
By default, when the -Xshare:dump
option is used, the
JVM runs in interpreter-only mode (as if the -Xint
option
were specified). This is required for generating deterministic output in
the shared archive file. I.e., the exact same archive will be generated,
bit-for-bit, every time you dump it. However, if deterministic output is
not needed, and you have a large classlist, you can explicitly add
-Xmixed
to the command-line to enable the JIT compiler.
This will speed up the archive creation.
Creating a Dynamic CDS Archive File with -XX:ArchiveClassesAtExit
Advantages of dynamic CDS archives are:
- They usually use less disk space, since they don't need to store the classes that are already in the static archive.
- They are created with one fewer step than the comparable static archive.
The following steps create a dynamic CDS archive file that contains
the classes that are used by the test.Hello
application,
excluding those that are already in the default CDS archive.
Create a dynamic CDS archive, named
hello.jsa
, that contains all the classes inhello.jar
loaded by the applicationtest.Hello
:java -XX:ArchiveClassesAtExit=hello.jsa -cp hello.jar Hello
Run the application
test.Hello
with the shared archivehello.jsa
:java -XX:SharedArchiveFile=hello.jsa -cp hello.jar test.Hello
Optional Repeat step 4 of the previous section to verify that the
test.Hello
application is using the class contained in thehello.jsa
shared archive.
It's also possible to create a dynamic CDS archive with a non-default static CDS archive. E.g.,
java -XX:SharedArchiveFile=base.jsa -XX:ArchiveClassesAtExit=hello.jsa -cp hello.jar Hello
To run the application using this dynamic CDS archive:
java -XX:SharedArchiveFile=base.jsa:hello.jsa -cp hello.jar Hello
(On Windows, the above path delimiter :
should be
replaced with ;
)
As mention above, the name of the static archive can be skipped:
java -XX:SharedArchiveFile=hello.jsa -cp hello.jar Hello
Creating CDS Archive Files with jcmd
The previous two sections require you to modify the application's start-up script in order to create a CDS archive. Sometimes this could be difficult, for example, if the application's class path is set up by complex routines.
The jcmd VM.cds
command provides a less intrusive way
for creating a CDS archive by connecting to a running JVM process. You
can create either a static:
jcmd <pid> VM.cds static_dump my_static_archive.jsa
or a dynamic archive:
jcmd <pid> VM.cds dynamic_dump my_dynamic_archive.jsa
To use the resulting archive file in a subsequent run of the application without modifying the application's start-up script, you can use the following technique:
env JAVA_TOOL_OPTIONS=-XX:SharedArchiveFile=my_static_archive.jsa bash app_start.sh
Note: to use jcmd <pid> VM.cds dynamic_dump
, the
JVM process identified by <pid>
must be started with
-XX:+RecordDynamicDumpInfo
, which can also be passed to the
application start-up script with the same technique:
env JAVA_TOOL_OPTIONS=-XX:+RecordDynamicDumpInfo bash app_start.sh
Creating Dynamic CDS Archive File with -XX:+AutoCreateSharedArchive
-XX:+AutoCreateSharedArchive
is a more convenient way of
creating/using CDS archives. Unlike the methods of manual CDS archive
creation described in the previous section, with
-XX:+AutoCreateSharedArchive
, it's no longer necessary to
have a separate trial run. Instead, you can always run the application
with the same command-line and enjoy the benefits of CDS
automatically.
java -XX:+AutoCreateSharedArchive -XX:SharedArchiveFile=hello.jsa -cp hello.jar Hello
If the specified archive file exists and was created by the same version of the JDK, then it will be loaded as a dynamic archive; otherwise it is ignored at VM startup.
At VM exit, if the specified archive file does not exist, it will be created. If it exists but was created with a different (but post JDK 19) version of the JDK, then it will be replaced. In both cases the archive will be ready to be loaded the next time the JVM is launched with the same command line.
If the specified archive file exists but was created by a JDK version prior to JDK 19, then it will be ignored: neither loaded at startup, nor replaced at exit.
Developers should note that the contents of the CDS archive file are
specific to each build of the JDK. Therefore, if you switch to a
different JDK build, -XX:+AutoCreateSharedArchive
will
automatically recreate the archive to match the JDK. If you intend to
use this feature with an existing archive, you should make sure that the
archive is created by at least version 19 of the JDK.
Restrictions on Class Path and Module Path
Neither the class path (
-classpath
and-Xbootclasspath/a
) nor the module path (--module-path
) can contain non-empty directories.Only modular JAR files are supported in
--module-path
. Exploded modules are not supported.The class path used at archive creation time must be the same as (or a prefix of) the class path used at run time. (There's no such requirement for the module path.)
The CDS archive cannot be loaded if any JAR files in the class path or module path are modified after the archive is generated.
If any of the VM options
--upgrade-module-path
,--patch-module
or--limit-modules
are specified, CDS is disabled. This means that the JVM will execute without loading any CDS archives. In addition, if you try to create a CDS archive with any of these 3 options specified, the JVM will report an error.
Performance Tuning Examples
You can use the Java advanced runtime options to optimize the performance of your applications.
Tuning for Higher Throughput
Use the following commands and advanced options to achieve higher throughput performance for your application:
java -server -XX:+UseParallelGC -XX:+UseLargePages -Xmn10g -Xms26g -Xmx26g
Tuning for Lower Response Time
Use the following commands and advanced options to achieve lower response times for your application:
java -XX:+UseG1GC -XX:MaxGCPauseMillis=100
Keeping the Java Heap Small and Reducing the Dynamic Footprint of Embedded Applications
Use the following advanced runtime options to keep the Java heap small and reduce the dynamic footprint of embedded applications:
-XX:MaxHeapFreeRatio=10 -XX:MinHeapFreeRatio=5
Note: The defaults for these two options are 70% and 40% respectively. Because performance sacrifices can occur when using these small settings, you should optimize for a small footprint by reducing these settings as much as possible without introducing unacceptable performance degradation.
Exit Status
The following exit values are typically returned by the launcher when
the launcher is called with the wrong arguments, serious errors, or
exceptions thrown by the JVM. However, a Java application may choose to
return any value by using the API call
System.exit(exitValue)
. The values are:
0
: Successful completion>0
: An error occurred