Oct 28, 2018 - Configuring the installer for this system's environment. Launching installer. Unrecognized option: -d64 Error: Could not create the Java Virtual.
The purpose of this guide is to help you identify potential issues and give you suggestions on how to proceed as you migrate your existing Java application to JDK 9. Every new Java SE release introduces some binary, source, and behavioral incompatibilities with previous releases. The modularization of the Java SE Platform brings many benefits, but also many changes. Code that uses only official Java SE Platform APIs and supported JDK-specific APIs should continue to work without change. Code that uses JDK-internal APIs should continue to run but should be migrated to use external APIs. To migrate your application, start by following the steps listed in. Migrating is an iterative process.
You’ll probably find it best to try running your program (this task) first, then complete these three tasks more or less in parallel:. When you run your application, look for warnings from the JVM about obsolete VM options.
If the VM fails to start, then look for removed options, because some VM flags that were deprecated in JDK 8 have been removed in JDK 9. If your application starts successfully, look carefully at your tests and ensure that the behavior is the same as on JDK 8. For example, a few early adopters have noticed that their dates and currencies are formatted differently.
Even if your program appears to run successfully, you should complete the rest of the steps in this guide and review the list of issues. For every tool and third-party library that you use, you may need to have an updated version that supports JDK 9. Check the websites for your third-party libraries and your tool vendors for a version of each library or tool that’s designed to work on JDK 9. If one exists, then download and install the new version. If you use Maven or Gradle to build your application, then make sure to upgrade to a more recent version that supports JDK 9. If you use an IDE to develop your applications, then it can help to migrate existing code. The NetBeans, Eclipse, and IntelliJ IDEs all have versions available that include JDK 9 support.
You can see the status of the testing of many Free Open Source Software (FOSS) projects with OpenJDK builds at on the OpenJDK wiki. Compiling your code with the JDK 9 compiler will ease migration to future releases since the code may depend on APIs and features which have been identified as problematic. However, it is not strictly necessary. If you need to compile your code with the JDK 9 compiler then take note of the following:. If you use the underscore character (') as a one-character identifier in source code, then your code won’t compile in JDK 9. Its use generates a warning in JDK 8, and an error in JDK 9.
As an example: static Object = new Object; This code generates the following error message from the compiler: MyClass.java:2: error: as of release 9, ' is a keyword, and may not be used as a legal identifier. If you use the -source and -target options with javac, then check the values that you use.
In JDK 9, javac uses a 'one plus three back' policy of supporting -source and -target options. The supported -source/-target values are 9 (the default), 8, 7, and 6 (6 is deprecated, and a warning is displayed when this value is used). In JDK 8, -source and -target values of 1.5/5 and earlier were deprecated and caused a warning to be generated.
In JDK 9, those values cause an error. javac -source 5 -target 5 Sample.java warning: options bootstrap class path not set in conjunction with -source 1.5 error: Source option 1.5 is no longer supported. Use 1.6 or later.
Error: Target option 1.5 is no longer supported. Use 1.6 or later. If possible, use the new -release flag instead of the -source and -target options. The -release N flag is conceptually a macro for: -source N -target N -bootclasspath $PATHTOrt.jarFORRELEASEN The valid arguments for the -release flag follow the same policy as for -source and -target, one plus three back.
Javac can recognize and process class files of all previous JDKs, going all the way back to JDK 1.0.2 class files. Critical internal JDK APIs such as sun.misc.Unsafe are still accessible in JDK 9, but most of the JDK’s internal APIs are not accessible at compile time. You may get compilation errors that indicate that your application or its libraries are dependent on internal APIs. To identify the dependencies, run the Java Dependency Analysis tool. If possible, update your code to use the supported replacement APIs. You may use the -add-exports option as a temporary workaround to compile source code with references to JDK internal classes.
You may see more deprecation warnings than previously. If you see deprecation with removal warnings, then you should address those to avoid future problems. A number of small changes have been made to javac to align it with the Java SE 9 Language Specification. You may encounter some source compatibility issues when recompiling. The contains details of changes to the javac compiler and source compatibility issues in JDK 9. Run the jdeps tool on your application to see what packages and classes your applications and libraries depend on. If you use internal APIs, then jdeps may suggest replacements to help you to update your code.
To look for dependencies on internal JDK APIs, run jdeps with the -jdkinternals option. For example, if you run jdeps on a class that calls sun.misc.BASE64Encoder, you’ll see: jdeps -jdkinternals Sample.class Sample.class - JDK removed internal API Sample - sun.misc.BASE64Encoder JDK internal API (JDK removed internal API) Warning: JDK internal APIs are unsupported and private to JDK implementation that are subject to be removed or changed incompatibly and could break your application. Please modify your code to eliminate dependency on any JDK internal APIs. For the most recent update on JDK internal API replacements, please check: JDK Internal API Suggested Replacement - - sun.misc.BASE64Encoder Use java.util.Base64 @since 1.8 If you use Maven, there’s a jdeps plugin available. For jdeps syntax, see in the Java Platform, Standard Edition Tools Reference. Keep in mind that jdeps is a static analysis tool, and static analysis of code doesn’t tell you everything.
If the code uses reflection to call an internal API, then jdeps doesn’t warn you. JDK 9 provides a new simplified version-string format. If your code relies on the version-string format to distinguish major, minor, security, and patch update releases, then you may need to update it. The format of the new version-string is: $MAJOR.$MINOR.$SECURITY.$PATCH For example, under the old scheme, the Java 9u5 security release would have the version string 1.9.05-b20. Under the new scheme, the short version of the same release is 9.0.1, and the long version is 9.0.1+20. This change affects java -version and related system properties, such as java.runtime.version, java.vm.version, java.specification.version, and java.vm.specification.version. A simple Java API to parse, validate, and compare version strings has been added.
See in Java Platform, Standard Edition Installation Guide,. Some tools and libraries use reflection to access parts of the JDK that are meant for internal use only. This illegal reflective access will be disabled in a future release of the JDK. In JDK 9, it is permitted by default and a warning is issued.
There are two options that allow you to break encapsulation in specific ways. You could use these in combination with -illegal-access= deny, or, as already mentioned, to suppress warnings. If you need to use an internal API that has been made inaccessible, then use the runtime option. You can also use -add-exports at compile time to access internal APIs.
If you have to allow code on the class path to do deep reflection to access nonpublic members, then use the option. If you want to suppress all reflective access warnings, then use the -add-exports and -add-opens options where needed. As a special case, if the is ALL-UNNAMED, then the source package is exported to all unnamed modules, whether they exist initially or are created later on. For example: -add-exports java.management/sun.management=ALL-UNNAMED This example allows code in all unnamed modules (code on the class path) to access the public members of public types in java.management/sun.management. If the code on the class path attempts to do deep reflection to access nonpublic members, then the code fails. If you have to allow code on the class path to do deep reflection to access nonpublic members, then use the -add-opens runtime option.
Some libraries do deep reflection, meaning setAccessible(true), so they can access all members, including private ones. You can grant this access using the -add-opens option on the java command line. No warning messages are generated as a result of using this option. If -illegal-access= deny, and you see IllegalAccessException or InaccessibleObjectException messages at runtime, you could use the -add-opens runtime option, basing the arguments upon the information shown in the exception message.
After you install JDK 9, if you look at the file system, you’ll notice that the directory layout is different from that of previous releases. Prior releases produced two types of runtime images: the JRE, which was a complete implementation of the Java SE Platform, and the JDK, which included the entire JRE in a jre/ directory, plus development tools and libraries.
In JDK 9, the JDK and JRE are two types of modular runtime images, where each contains the following directories:. bin — contains binary executables. conf — contains.properties,.policy, and other kinds of files intended to be edited by developers, deployers, and end users. These files were formerly found in the lib directory or its subdirectories. lib — contains dynamically linked libraries and the complete internal implementation of the JDK.
There are still separate JDK and JRE downloads, but each has the same directory structure. The JDK image contains the extra tools and libraries that have historically been found in the JDK. There are no jdk/ versus jre/ wrapper directories, and binaries (such as the java command) aren’t duplicated. See and in Java Platform, Standard Edition Installation Guide.
JDK 9 maintains the hierarchy of class loaders that existed since the 1.2 release. However, the following changes have been made to implement the module system:.
The application class loader is no longer an instance of URLClassLoader but, rather, of an internal class. It is the default loader for classes in modules that are neither Java SE nor JDK modules. The extension class loader has been renamed; it is now the platform class loader. All classes in the Java SE Platform are guaranteed to be visible through the platform class loader.
In addition, the classes in modules that are standardized under the Java Community Process but not part of the Java SE Platform are guaranteed to be visible through the platform class loader. Just because a class is visible through the platform class loader does not mean the class is actually defined by the platform class loader. Some classes in the Java SE Platform are defined by the platform class loader while others are defined by the bootstrap class loader.
Applications should not depend on which class loader defines which platform class. The changes in JDK 9 may impact code that creates class loaders with null (that is, the bootstrap class loader) as the parent class loader and assumes that all platform classes are visible to the parent. Such code may need to be changed to use the platform class loader as the parent (see ).
The platform class loader is not an instance of URLClassLoader, but, rather, of an internal class. The bootstrap class loader is still built-in to the Java Virtual Machine and represented by null in the ClassLoader API. It defines the classes in a handful of critical modules, such as java.base. As a result, it defines far fewer classes than in JDK 8, so applications that are deployed with -Xbootclasspath/a or that create class loaders with null as the parent may need to change as described previously. Class and resource files previously stored in lib/rt.jar, lib/tools.jar, lib/dt.jar and various other internal JAR files are stored in a more efficient format in implementation-specific files in the lib directory.
The removal of rt.jar and similar files leads to issues in these areas:. In JDK 9, doesn’t return a URL pointing to a JAR file (because there are no JAR files). Instead, it returns a jrt URL, which names the modules, classes, and resources stored in a runtime image without revealing the internal structure or format of the image. For example: ClassLoader.getSystemResource('java/lang/Class.class'); When run on JDK 8, this method returns a JAR URL of the form: jar:file:/usr/local/jdk8/jre/lib/rt.jar!/java/lang/Class.class which embeds a file URL to name the actual JAR file within the runtime image.
A modular image doesn’t contain any JAR files, so URLs of this form make no sense. On JDK 9, this method returns: jrt:/java.base/java/lang/Class.class. The API and security policy files use URLs to name the locations of code bases that are to be granted specific permissions. See in Java Platform, Standard Edition Security Developer's Guide. Components of the runtime system that require specific permissions are currently identified in the conf/security/java.policy file by using file URLs.
IDEs and other development tools require the ability to enumerate the class and resource files stored in a runtime image, and to read their contents directly by opening and reading rt.jar and similar files. This isn’t possible with a modular image. In previous releases, the extension mechanism made it possible for the runtime environment to find and load extension classes without specifically naming them on the class path. In JDK 9, if you need to use the extension classes, ensure that the JAR files are on the class path.
The javac compiler and java launcher will exit if the java.ext.dirs system property is set, or if the lib/ext directory exists. To additionally check the platform-specific systemwide directory, specify the -XX:+CheckEndorsedAndExtDirs command-line option. This causes the same exit behavior to occur if the directory exists and isn’t empty. The extension class loader is retained in JDK 9 and is specified as the platform class loader (see.) The following error means that your system is configured to use the extension mechanism. The java.endorsed.dirs system property and the lib/endorsed directory are no longer present. The javac compiler and java launcher will exit if either one is detected. In JDK 9, you can use upgradeable modules or put the JAR files on the class path.
This mechanism was intended for application servers to override components used in the JDK. Packages to be updated would be placed into JAR files, and the system property java.endorsed.dirs would tell the Java runtime environment where to find them. If a value for this property wasn’t specified, then the default of $JAVAHOME/lib/endorsed was used. In JDK 8, you can use the -XX:+CheckEndorsedAndExtDirs command-line argument to check for such directories anywhere on the system.
In JDK 9, the javac compiler and java launcher will exit if the java.endorsed.dirs system property is set, or if the lib/endorsed directory exists. The following error means that your system is configured to use the endorsed standards override mechanism. 'HKEYLOCALMACHINE SOFTWARE JavaSoft Java Runtime Environment' '@CurrentVersion'=1.8 If the JDK is installed, the Java Development Kit key replaces the Java Runtime Environment key in the above example. If there are two versions of JDK or JRE installed, one with the new version-string format introduced in JDK 9, and the other with the older version format, then there will be two different Java-related CurrentVersion strings in the registry. One indicates the highest version number prior to JDK 9, and the other indicates the highest version number since JDK 9. The Java team is committed to backward compatibility.
If an application runs in JDK 8, then it will run on JDK 9 as long as it uses APIs that are supported and intended for external use. These include:. JCP standard, java., javax. JDK-specific APIs, some com.sun., some jdk. Supported APIs can be removed from the JDK, but only with notice.
Find out if your code is using deprecated APIs by running the static analysis tool. Java. APIs that have been removed in JDK 9 include the previously deprecated methods from the java.util.logging.LogManager and java.util.jar.Pack200 packages. The nonstandard package com.sun.image.codec.jpeg has been removed. Use the Java Image I/O API instead. The com.sun.image.codec.jpeg package was added in JDK 1.2 as a nonstandard way of controlling the loading and saving of JPEG format image files. It has never been part of the platform specification.
In JDK 1.4, the Java Image I/O API was added as a standard API, residing in the javax.imageio package. It provides a standard mechanism for controlling the loading and saving of sampled image formats and requires all compliant Java SE implementations to support JPEG based on the Java Image I/O specification. In JDK 9, you can choose to build and run your application against any subset of the modules in the Java runtime image, without needing to rely on predefined profiles. Profiles, introduced in Java SE 8, define subsets of the Java SE Platform API that can reduce the static size of the Java runtime on devices that have limited storage capacity. The tools in JDK 8 support three profiles, compact1, compact2, and compact3. For the API composition of each profile, see and in the JDK 8 documentation. In JDK 8, you use the -profile option to specify the profile when running the javac and java commands.
In JDK 9, the -profile option is supported by javac only in conjunction with the -release 8 option, and isn’t supported by java. JDK 9 lets you choose the modules that are used at compile and run time. By specifying modules with the new -limit-modules option, you can obtain the same APIs that are in the compact profiles.
This option is supported by both the javac and java commands, as shown in the following examples: javac -limit-modules java.base,java.logging MyApp.java java -limit-modules java.base,java.logging MyApp. In JDK 9, the Unicode Consortium's Common Locale Data Repository (CLDR) data is enabled as the default locale data, so that you can use standard locale data without any further action.
In JDK 8, although CLDR locale data is bundled with the JRE, it isn’t enabled by default. Code that uses locale-sensitive services such as date, time, and number formatting may produce different results with the CLDR locale data. Remember that even System.out.printf is locale-aware. To enable behavior compatible with JDK 8, set the system property java.locale.providers to a value with COMPAT ahead of CLDR, for example, java.locale.providers=COMPAT,CLDR. See in the Java Platform, Standard Edition Internationalization Guide.
In JDK 9, the modules that contain CORBA or the APIs shared between Java SE and Java EE are not resolved by default when you compile or run code on the class path. The ability to request a version of the JRE that isn’t the JRE being launched at launch time is removed in JDK 9.
Modern applications are typically deployed using Java Web Start (JNLP), native OS packaging systems, or active installers. These technologies have their own methods to manage the JREs needed, by finding or downloading and updating the required JRE, as needed. This makes the launcher's launch-time JRE version selection obsolete. In the previous releases, you could specify what JRE version (or range of versions) to use when starting an application.
Version selection was possible through both a command-line option and manifest entry in the application's JAR file. JNLP (Java Network Launch Protocol) has been updated to remove inconsistencies, make code maintenance easier, and enhance security. JNLP has been updated as follows:. & instead of & in JNLP files. The JNLP file syntax conforms to the XML specification and all JNLP files should be able to be parsed by standard XML parsers. JNLP files let you specify complex comparisons.
Previously, this was done by using the ampersand ( &), but this isn’t supported in standard XML. If you’re using & to create complex comparisons, then replace it with & in your JNLP file. & is compatible with all versions of JNLP. Comparing numeric version element types against nonnumeric version element types. Previously, when an int version element was compared with another version element that couldn’t be parsed as an int, the version elements were compared lexicographically by ASCII value. In JDK 9, if the element that can be parsed as an int is a shorter string than the other element, it will be padded with leading zeros before being compared lexicographically by ASCII value. This ensures there can be no circularity.
In the case where both version comparisons and a JNLP servlet are used, you should use only numeric values to represent versions. Component extensions with nested resources in java (or j2se) elements. This is permitted in the specification. It was previously supported, but this support wasn’t reflected in the specification. FX XML extension. The JNLP specification has been enhanced to add a type attribute to application-desc element, and add the subelement param in application-desc (as it already is in applet-desc). This doesn’t cause problems with existing applications because the previous way of specifying a JavaFX application is still supported.
See the JNLP specification updates at. If your application previously required the Java Cryptography Extension (JCE) Unlimited Strength Jurisdiction Policy Files, then you no longer need to download or install them. They are included in the JDK and are activated by default. If your country or usage requires a more restrictive policy, the limited Java cryptographic policy files are still available. If you have requirements that are not met by either of the policy files provided by default, then you can customize these policy files to meet your needs.
See the crypto.policy Security property in the /conf/security/java.security file, or in the Java Platform, Standard Edition Security Developer's Guide. You are advised to consult your export/import control counsel or attorney to determine the exact requirements. DefNew + CMS. ParNew + SerialOld. Incremental CMS The foreground mode for CMS has also been removed. The command-line flags that were removed are -Xincgc, -XX:+CMSIncrementalMode, -XX:+UseCMSCompactAtFullCollection, -XX:+CMSFullGCsBeforeCompaction, and -XX:+UseCMSCollectionPassing. The command-line flag -XX:+UseParNewGC no longer has an effect.
The ParNew flag can be used only with CMS and CMS requires ParNew. Thus, the -XX:+UseParNewGC flag has been deprecated and is eligible for removal in a future release. Garbage collection (GC) logging uses the JVM unified logging framework, and there are some differences between the new and the old logs. Any GC log parsers that you’re working with will probably need to change.
You may also need to update your JVM logging options. All GC-related logging should use the gc tag (for example, —Xlog:gc), usually in combination with other tags. The —XX:+PrintGCDetails and -XX:+PrintGC options have been deprecated.
See in the Java Platform, Standard Edition Tools Reference. The hprof agent library has been removed. The hprof agent was written as demonstration code for the and wasn’t intended to be a production tool. The useful features of the hprof agent have been superseded by better alternatives, including some that are included in the JDK. For creating heap dumps in the hprof format, use a diagnostic command ( jcmd) or the jmap tool:. Diagnostic command: jcmd GC.heapdump.
jmap: jmap -dump. For CPU profiler capabilities, use the Java Flight Recorder, which is bundled with the JDK. The IIOP transport support from the JMX RMI Connector along with its supporting classes have been removed in JDK 9. In JDK 8, support for the IIOP transport was downgraded from required to optional.
This was the first step in a multirelease effort to remove support for the IIOP transport from the JMX Remote API. In JDK 9, support for IIOP has been removed completely. Public API changes include:. The javax.management.remote.rmi.RMIIIOPServerImpl class has been deprecated. Upon invocation, all its methods and constructors throw java.lang.UnsupportedOperationException with an explanatory message. Two classes, org.omg.stub.javax.management.rmi.RMIConnectionStub, and org.omg.stub.javax.management.rmi.RMIConnectionTie, aren’t generated. The java.awt.Desktop class contains replacements for the APIs in the Apple–specific com.apple.eawt and com.apple.eio packages.
The new APIs supersede the macOS APIs and are platform-independent. The APIs in the com.apple.eawt and com.apple.eio packages are encapsulated, so you won’t be able to compile against them in JDK 9. However, they remain accessible at runtime, so existing code that is compiled to old versions continues to run.
Eventually, libraries or applications that use the internal classes in the apple and com.apple packages and their subpackages will need to migrate to the new API. The com.apple.concurrent and apple.applescript packages are removed without any replacement. After you have your application working on JDK 9, here are some suggestions that can help you get the most from the Java SE Platform:. Read to learn about new features of JDK 9. If needed, cross-compile to an older release of the platform using the new –release flag in the tool.
Take advantage of your IDE’s suggestions for updating your code with the latest features. Find out if your code is using deprecated APIs by running the static analysis tool. As already mentioned in this guide, APIs can be removed from the JDK, but only with advance notice. Get familiar with new features like multi-release JAR files (see ).
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