Building a UI toolkit for many different platforms is a complex and challenging endeavor. It requires platform specific tools such as C compilers as well as portable tools like Gradle and the JDK. Which tools must be installed differs from platform to platform. While the OpenJFX build system was designed to remove as many build hurdles as possible, it is necessary to build native code and have the requisite compilers and toolchains installed. On Mac and Linux this is fairly easy, but setting up Windows is more difficult.
For a ready made build, you can download it from the JDK 9, download page (or you can grab a JDK 10 early access build), or try the Community Build page.
If you are looking for instructions to build FX for JDK 8uNNN, they have been archived here.
Before you start
Do you really want to build OpenJFX? We would like you to, but JavaFX is bundled by default in desktop editions of JDK 8, JDK 9, and the JDK 10 early access builds. There are also some great community builds that may work for you.
Starting with Java 9, and the introduction of the module system, The FX modules are now an integral part of the runtime environment for the desktop. Because of this tie, there is currently no provision or capability for the output of the OpenJFX 9 or later build to be used as an overlay. It is still possible however to develop and enhance OpenJFX, and use that result to build an OpenJDK.
We are exploring making this easier, by enabling a developer to build a set of javafx.* modules that can be used with a clean OpenJDK build (without the javafx.* modules). Stay tuned.
Platform Prerequisites
Windows
You will need Windows 7 or later (Windows 10 is recommended) 64-bit OS
You need to have the following tools installed:
- Cygwin. Some packages to make sure are installed are:
- mercurial (hg)
- openssh
- zip
- unzip
- make (needed to compile media)
- makedepend (needed for media)
- Microsoft Visual Studio 2017, either Professional or Community edition
- Microsoft DirectShow header files – If you build media you will need the DirectShow header files from the Microsoft Windows SDK v7.1, installed in its default location of "C:\Program Files\Microsoft SDKs\Windows\v7.1"
- DirectX SDK June 2010 (TODO: this should no longer be needed – verify this)
Microsoft DirectX SDK (June 2010) headers are required for building the JavaFX SDK. This DirectX SDK can be downloaded from Microsoft DirectX SDK (June 2010). If the link above becomes obsolete, the SDK can be found from the Microsoft Download Site (search with "DirectX SDK June 2010"). The location of this SDK will normally be set with the environment variable DXSDK_DIR at installation time. The default location is normally "C:/Program Files/Microsoft DirectX SDK (June 2010)/". If DXSDK_DIR is not set, the build process may look for it in the default location or "C:/DXSDK/".
If you build WebKit (it is not built by default) you will need the following additional tools:
- Cmake 3.8.2 or later, available from the Cmake download site
- Additional cygwin tools:
- bison
- flex
- g++
- gperf
- perl
- python
- ruby
You will likely need to set the following env variables to point to your VS 2017 installation, since Microsoft no longer sets such variables. This presumes that you are using build 14.11.25503 of the Community edition of Visual Studio 2017. You should adjust it as needed for your system.
export VS150COMNTOOLS="C:\\Program Files (x86)\\Microsoft Visual Studio\\2017\\Community\\VC\\Auxiliary\\Build" export JAVA_HOME="C:/Program Files/Java/jdk-10" export MSVC_VER=14.11.25503
Note the use of the double backslash in the VS150COMNTOOLS env var. This is needed because the cygwin shell uses the '\' as an escape character. With JAVA_HOME it is easier to just set it using forward slashes (although backslashes are fine as long as you escape them).
Mac
You will need macOS 10.12 (Sierra) or later.
Install the following software:
- Xcode 9.1 or later
- Xcode developer command line tools – you can install them by using the menus within Xcode: XCode -> Preferences -> Downloads -> Components
- mercurial (hg)
If you build WebKit (it is not built by default) you will need the following additional tools:
- Cmake 3.8.2 or later, available from the Cmake download site
- gperf
Linux
Setting up a Linux build configuration is fairly straightforward. These build instructions were used for Ubuntu 16.04.
Ubuntu 16.04
First, run the following command to install all the required development packages:
TODO: verify and update this (I think many are unused)
sudo apt-get update sudo apt-get install ksh libasound2-dev libgl1-mesa-dev \ libgstreamer0.10-dev libgstreamer-plugins-base0.10-dev libjpeg-dev \ libpng-dev libx11-dev libxml2-dev libxslt1-dev libxt-dev \ libxxf86vm-dev pkg-config x11proto-core-dev \ x11proto-xf86vidmode-dev libavcodec-dev mercurial \
libgtk2.0-dev libgtk-3-dev \ libxtst-dev libudev-dev libavformat-dev
If you build WebKit (it is not built by default) you will need the following additional tools:
- Cmake 3.8.2 or later, available from the Cmake download site
- bison
- flex
- gperf
- ruby
The following should satisfy the requirements (but check the version of cmake) :
sudo apt-get install cmake bison flex gperf ruby
Oracle Enterprise Linux 7 and Fedora 21
We use Oracle Linux 7 to build the javafx.* modules that we ship with the Oracle JDK releases. Here are the packages you will need:
TODO: verify and update this
yum install mercurial bison flex gperf ksh pkgconfig \
libpng12-devel libjpeg-devel libxml2-devel \
libxslt-devel systemd-devel glib2-devel gtk2-devel \
libXtst-devel pango-devel freetype-devel
Common Prerequisites
JDK 9.x or JDK 10 EA (build 35 or later)
Download and install JDK 9 or later to use as the boot JDK to build and test OpenJFX. We recommend either JDK 9.0.1 or a recent JDK 10 Early Access build.
Mercurial
OpenJFX, as with OpenJDK, uses Mercurial as the source control system. You must install some support for using Mercurial. Many (if not all) IDEs include built in support, although the tooling is generally not as good as you might get from a standalone tool.
For Linux, the Mercurial package is included in the list of required packaged that were installed.
Popular options include SourceTree from Atlassian, TortoiseHg for Windows, or the command line tools from Mercurial. On Windows, you can also install Mercurial as a cygwin package.
Gradle
Gradle is the primary build tool for building OpenJFX. We currently use Gradle 4.3 for jfx-dev (IMPORTANT: Only this version is regularly tested).
Note: gradle is available as a Ubuntu package, but check the version. This command should work after you set JAVA_HOME:
gradle -version
Ant
You will need Apache Ant 1.8.2 to build the OpenJFX apps (IMPORTANT: there are known issues with later versions of ant, so get exactly version 1.8.2).
Environment Variables
At a minimum, you will need to have gradle in your path:
- set JAVA_HOME and JDK_HOME to point to the root of your jdk-9 or jdk-10 EA release.
- add $JAVA_HOME/bin to your PATH
- add gradle-4.3/bin to your PATH
- add apache-ant-1.8.2/bin to your PATH
Note: on windows, the JAVA_HOME and JDK_HOME variables must be in DOS format (e.g., "C:/Program Files/..." rather than "/cygdrive/c/Program Files/..."), although you can use forward slashes ('/'). Test your settings with:
"$JAVA_HOME/bin/java" -version gradle -version ant -version
IMPORTANT: Any time you change env settings or install new software after a failed build of JavaFX you should execute the following three commands:
gradle --stop rm -rf build gradle clean
The first is needed to stop any gradle daemons that might be running (by default gradle starts a daemon that is used to speed up subsequent builds). There is a bug in the gradle daemon that causes gradle to ignore any env variables set after the daemon is started (see JDK-8193288). Additionally, on Windows platforms, the gradle daemon can sometimes interfere with your ability to delete files that it keeps open. If you run into problems you can stop the gradle daemon with "gradle --stop" (or disable the gradle daemon altogether).
The second is needed because the OpenJFX build caches the results of a previous configuration, in such a way that it can cause gradle clean to fail.
Getting the Sources
All OpenJFX sources are held in mercurial repositories. As mentioned in Repositories and Releases, we have several different repositories for you to choose from, although most developers should use the mainline jfx-def repo.
# for the active development stream, currently targeted for JDK 11 hg clone http://hg.openjdk.java.net/openjfx/jfx-dev/rt
(Note: Historically you also had to clone the top "jfx" repository in the forest that you cared about. However we have modified our approach, such that we no longer promote the use of a forest, and instead are putting all of our sources in a single repository, named "rt").
Using Gradle on The Command Line
Before diving directly into building OpenJFX, lets get our feet wet by learning what kinds of things we can call from the command line, and how to get help when we need it. The first command you should execute is tasks:
$ gradle tasks ... :tasks ------------------------------------------------------------ All tasks runnable from root project ------------------------------------------------------------ Default tasks: sdk Basic tasks ----------- buildModuleBaseLinux - creates javafx.base property files buildModuleGraphicsLinux - copies javafx.graphics native libraries buildModuleLibsLinux buildModuleMediaLinux - copies javafx.media native libraries buildModulePackagerExeLinux - copies jdk.packager executable buildModulePackagerLibsLinux - copies jdk.packager libraries buildModuleSWTLinux - copies SWT JAR buildModuleWebLinux - copies javafx.web native libraries clean - Deletes the build directory and the build directory of all sub projects cleanAll - Scrubs the repo of build artifacts javadoc - Generates the JavaDoc for all the public API javafxSwtLinux - Creates the javafx-swt.jar for the linux target sdkLinux Build tasks ----------- antpluginClasses - Assembles antplugin classes. assemble - Assembles the outputs of this project. build - Assembles and tests this project. buildDependents - Assembles and tests this project and all projects that depend on it. buildJavaPackager buildModuleLinux buildModulesLinux buildModuleZipLinux buildNeeded - Assembles and tests this project and all projects it depends on. buildRunArgsLinux ccLinuxFont - Compiles native sources for font for linux ccLinuxFontFreetype - Compiles native sources for fontFreetype for linux ccLinuxFontPango - Compiles native sources for fontPango for linux ccLinuxGlassGlass - Compiles native sources for glass for linux for variant Glass ccLinuxGlassGlassgtk2 - Compiles native sources for glass for linux for variant Glassgtk2 ccLinuxGlassGlassgtk3 - Compiles native sources for glass for linux for variant Glassgtk3 ccLinuxIio - Compiles native sources for iio for linux ccLinuxPrism - Compiles native sources for prism for linux ccLinuxPrismES2 - Compiles native sources for prismES2 for linux ccLinuxPrismSW - Compiles native sources for prismSW for linux classes - Assembles main classes. clean - Deletes the build directory. cleanNative - Clean all native libraries and objects for Graphics cleanNativeDecora - Clean native objects for Decora cleanNativeFont - Clean native objects for font cleanNativeFontFreetype - Clean native objects for fontFreetype cleanNativeFontPango - Clean native objects for fontPango cleanNativeGlass - Clean native objects for glass cleanNativeIio - Clean native objects for iio cleanNativePrism - Clean native objects for prism cleanNativePrismES2 - Clean native objects for prismES2 cleanNativePrismSW - Clean native objects for prismSW compileLinuxLauncher - Compiles native sources for the application co-bundle launcher compileLinuxLibrary - Compiles native sources for the application co-bundle launcher library createMSPfile jar - Assembles a jar archive containing the main classes. jslcClasses - Assembles jslc classes. linkLinuxFont - Creates native dynamic library for font for linux linkLinuxFontFreetype - Creates native dynamic library for fontFreetype for linux linkLinuxFontPango - Creates native dynamic library for fontPango for linux linkLinuxGlassGlass - Creates native dynamic library for glass for linux for variant Glass linkLinuxGlassGlassgtk2 - Creates native dynamic library for glass for linux for variant Glassgtk2 linkLinuxGlassGlassgtk3 - Creates native dynamic library for glass for linux for variant Glassgtk3 linkLinuxIio - Creates native dynamic library for iio for linux linkLinuxLauncher - Links native dynamic library for the application co-bundle launcher linkLinuxLibrary - Links native dynamic library for the application co-bundle launcher library linkLinuxPrism - Creates native dynamic library for prism for linux linkLinuxPrismES2 - Creates native dynamic library for prismES2 for linux linkLinuxPrismSW - Creates native dynamic library for prismSW for linux native - Compiles and Builds all native libraries for Graphics nativeDecora - Generates JNI headers, compiles, and builds native dynamic library for Decora nativeFont - Generates JNI headers, compiles, and builds native dynamic library for font for all compile targets nativeFontFreetype - Generates JNI headers, compiles, and builds native dynamic library for fontFreetype for all compile targets nativeFontPango - Generates JNI headers, compiles, and builds native dynamic library for fontPango for all compile targets nativeGlass - Generates JNI headers, compiles, and builds native dynamic library for glass for all compile targets nativeIio - Generates JNI headers, compiles, and builds native dynamic library for iio for all compile targets nativePrism - Generates JNI headers, compiles, and builds native dynamic library for prism for all compile targets nativePrismES2 - Generates JNI headers, compiles, and builds native dynamic library for prismES2 for all compile targets nativePrismSW - Generates JNI headers, compiles, and builds native dynamic library for prismSW for all compile targets shadersClasses - Assembles shaders classes. shimsClasses - Assembles shims classes. stubClasses - Assembles stub classes. testapp1Classes - Assembles testapp1 classes. testapp2Classes - Assembles testapp2 classes. testapp3Classes - Assembles testapp3 classes. testapp4Classes - Assembles testapp4 classes. testapp5Classes - Assembles testapp5 classes. testapp6Classes - Assembles testapp6 classes. testClasses - Assembles test classes. toolsClasses - Assembles tools classes. Build Setup tasks ----------------- init - Initializes a new Gradle build. wrapper - Generates Gradle wrapper files. Documentation tasks ------------------- javadoc - Generates Javadoc API documentation for the main source code. Help tasks ---------- buildEnvironment - Displays all buildscript dependencies declared in root project 'rt'. components - Displays the components produced by root project 'rt'. [incubating] dependencies - Displays all dependencies declared in root project 'rt'. dependencyInsight - Displays the insight into a specific dependency in root project 'rt'. dependentComponents - Displays the dependent components of components in root project 'rt'. [incubating] help - Displays a help message. model - Displays the configuration model of root project 'rt'. [incubating] projects - Displays the sub-projects of root project 'rt'. properties - Displays the properties of root project 'rt'. tasks - Displays the tasks runnable from root project 'rt' (some of the displayed tasks may belong to subprojects). Verification tasks ------------------ check - Runs all checks. test - Runs the unit tests. To see all tasks and more detail, run gradle tasks --all To see more detail about a task, run gradle help --task <task> BUILD SUCCESSFUL in 4s 1 actionable task: 1 executed
The tasks task is extremely helpful. You use it to discover all the other things you can do with this build file. You notice at the top of the output the phrase "All tasks runnable from root project". The "root" project is "javafx". That is, we are in the root project. Below the root project are a series of sub projects, some of which are referred to as modules or "components". But more about those later.
Gradle then tells us what the default tasks are. In this case, our default task is the 'sdk' task. This is the task that will be executed if you just call 'gradle' alone without providing any additional arguments. After this comes a listing of different tasks, broken out by group. The first group is the "Basic" group which contains the tasks you may find yourself using most often. These are all named and have a description provided. For example, if I wanted to execute the 'clean' task, then I would do so like this:
$ gradle clean
Finally, the tasks task gives us a useful hint that we can pass the --all argument in order to see all of the tasks in more detail. This produces a lot more output, but really gives an in depth look at what tasks are available for you to call.
I mentioned above that our root project is called "rt", and that we have sub-projects in the gradle build. To see all of the projects available to you, execute the projects task (which you will notice was in the "Help tasks" group produced by the tasks task). This lists not just what projects are available, but what their name is, and what the project hierarchy is.
$ gradle projects ... :projects ------------------------------------------------------------ Root project ------------------------------------------------------------ Root project 'rt' +--- Project ':apps' +--- Project ':base' +--- Project ':controls' +--- Project ':fxml' +--- Project ':fxpackager' +--- Project ':fxpackagerservices' +--- Project ':graphics' +--- Project ':jmx' +--- Project ':media' +--- Project ':swing' +--- Project ':swt' +--- Project ':systemTests' \--- Project ':web' To see a list of the tasks of a project, run gradle <project-path>:tasks For example, try running gradle :apps:tasks BUILD SUCCESSFUL in 1s 1 actionable task: 1 executed kcr@beethoven:~/javafx/openjfx/jfx-kcr/rt$
Projects in gradle are named according to their depth. So the root project is simply named "rt" (or whatever your top directory is named). The immediate subprojects are all prefixed with a ":". Sub-subprojects have their parents in their name, for example, ":graphics:effects-jsl". When you execute a command such as gradle assemble what actually happens is that Gradle locates the assemble task on all projects and executes them. (TODO Is this entirely accurate?)
There are a couple other tricks-of-the-trade that you should be aware of. You can execute any gradle command with --info or --debug in order to get more output. Running in --info mode provides some additional debugging output that is very useful when things go wrong.
One more trick is the --profile argument. You can perform any gradle task and use the --profile argument. This will cause gradle to keep track of how long various parts of the build took, and will produce an HTML report in build/reports/profile. The report breaks down how much time was spent in configuration, dependency resolution, and task execution. It further breaks it down by project. This gives useful metrics for tracking down which parts of the build take the longest and hopefully tighten up the build times.
Build and Test
There are three main things you may want to do on a regular basis when working on JavaFX: building, testing, and creating documentation. Lets look at each of these in turn.
The simplest basic task to build is the sdk task. The sdk task will compile all Java sources and all native sources for your target platform. It is the default task which is executed if you do not supply a specific task to run. It will create the appropriate sdk directory and populate it with the native dynamic libraries and the jfxrt.jar. Because the SDK is not distributed with documentation, the javadocs are not created as part of the sdk task by default. Once the sdk task has completed, you will have and SDK distribution which you could run against or give to somebody else to run.
$ gradle ... :buildModulesLinux :buildRunArgsLinux :buildModules :createTestArgfilesLinux :sdkLinux :sdk BUILD SUCCESSFUL in 1m 48s 127 actionable tasks: 127 executed
You can find the built SDK in the build/modular-sdk directory:
$ pwd /Users/kcr/jfx-dev/rt $ ls -l build/ -rw-r--r-- 1 kcr kcr 1621 Dec 22 09:54 compile.args drwxr-xr-x 2 kcr kcr 4096 Dec 22 09:54 libs/ -rw-r--r-- 1 kcr kcr 47 Dec 22 09:54 linux_freetype_tools.properties -rw-r--r-- 1 kcr kcr 681 Dec 22 09:54 linux_gtk2.properties -rw-r--r-- 1 kcr kcr 799 Dec 22 09:54 linux_gtk3.properties -rw-r--r-- 1 kcr kcr 255 Dec 22 09:54 linux_pango_tools.properties drwxr-xr-x 9 kcr kcr 4096 Dec 22 09:54 modular-sdk/ -rw-r--r-- 1 kcr kcr 1916 Dec 22 09:54 run.args -rw-r--r-- 1 kcr kcr 1379 Dec 22 09:54 run.java.policy -rw-r--r-- 1 kcr kcr 1304 Dec 22 09:54 test.java.policy -rw-r--r-- 1 kcr kcr 1551 Dec 22 09:54 testcompile.args -rw-r--r-- 1 kcr kcr 1846 Dec 22 09:54 testrun.args drwxr-xr-x 3 kcr kcr 4096 Dec 22 09:54 tmp/
The sdk task will build an OpenJFX SDK for your particular platform. Gradle automatically handles the downloading of all dependencies (such as Antlr and SWT).
For more information on build properties, see Customizing the Build.
Platform Builds
NOTE: cross-build support is currently untested in the mainline jfx-dev/rt repo
The build is configured to support cross builds, that is, the ability to build an SDK for a platform other than the one you are building from. There are multiple gradle files located in buildSrc which represent specific compile targets. These include:
- win.gradle
- mac.gradle
- linux.gradle
- android.gradle
- ios.gradle
- armv6sf.gradle
- armv6hf.gradle
Each of these have specific prerequisites that must be met before they can be built. win.gradle can only be used on Windows, mac.gradle on Mac, and linux.gradle on Linux. Android can be cross built from Mac, Windows, or Linux so long as the Android SDK and NDK are installed and the build knows where to find them. iOS can be cross built on Mac. ARM (soft float and hard float) can be cross built from Linux.
By default, the OpenJFX build system will only build the SDK for the desktop platform you are building from. To ask it to build for a specific compile target, you must pass a COMPILE_TARGETS property to the build system, instructing it which to build. This is a comma separated list. Assuming you have already setup the prerequisites for building ARM (for example, when targeting the Raspberry PI), you would invoke gradle like this:
$ gradle -PCOMPILE_TARGETS=armv6hf
Customizing the Build
The build can be customized fairly extensively through the use of Gradle properties. Gradle provides many ways to supply properties to the build system. However the most common approach will be to use a gradle.properties file located in the rt directory. Simply make a copy of gradle.properties.template and then edit the resulting gradle.properties file to customize your build.
$ cp gradle.properties.template gradle.properties
The gradle.properties file that you have just created is heavily documented and contains information on all the different configuration options at your disposal.
Arguably the most important property in the build is the JDK_HOME property, which will be set to the value of $JAVA_HOME if you haven't explicitly set it. Almost all other properties are derived automatically from this one. The JDK_HOME is by default based on the java.home System property, which is set automatically by the JVM based on which version of Java is executed. Typically, then, the version of Java you will be using to compile with will be the version of Java you have setup on your path. You can of course specify the JDK_HOME yourself. Note also that on Windows, the version of the JDK you have set as JDK_HOME will determine whether you build 32 or 64 bit binaries.
Testing
The next basic task which you may want to perform is test. The test task will execute the unit tests. You generally will execute the top level test because unlike with Ant, Gradle will only re-execute those tests which have changed (or were dependent on code that was changed) on subsequent runs. You can of course execute gradle cleanTest in order to clean all the test results so they will run fresh. Or, if you want to execute only those tests related to a single project, you can do so in the normal fashion:
$ gradle :base:test The CompileOptions.useAnt property has been deprecated and is scheduled to be removed in Gradle 2.0. There is no replacement for this property. :base:processVersion UP-TO-DATE :build-tools:generateGrammarSource UP-TO-DATE :build-tools:compileJava UP-TO-DATE :build-tools:processResources UP-TO-DATE :build-tools:classes UP-TO-DATE :build-tools:jar UP-TO-DATE :base:compileJava UP-TO-DATE :base:processResources UP-TO-DATE :base:classes UP-TO-DATE :base:compileTestJava UP-TO-DATE :base:processTestResources UP-TO-DATE :base:testClasses UP-TO-DATE > Building > :base:test > 3411 tests completed, 45 skipped
Gradle gives helpful output during execution of the number of tests completed and the number skipped without dumping out lots of output to the console (unless you opt for --info). Also, once the tests complete, an HTML report is dumped to the project's build/reports/test directory (for example, modules/base/build/reports/test):
For the sake of performance, most of the tests are configured to run in the same VM. However some tests by design cannot be run in the same VM, and others cannot yet run in the same VM due to bugs or issues in the test. In order to improve the quality of the project we need to run as many tests as possible in the same VM. The more tests we can run on pre-integration the less likely we are to see failures leak into master. Being able to run 20,000 tests in a minute is extremely useful, but not possible, unless they run in the same VM. Something to keep in mind.
Testing with JDK 9 or JDK 10
Using the results of a modular OpenJFX build is quite simple. A "run" args file can be used to point to the overriding modules that are in your build. (args file support for java was added in JDK 9) The file build/run.args and build/compile.args are created during the FX build process. The run.args file contains full paths to the overriding modules and shared libraries, and so must be recreated if you are using a copied or downloaded module set (for example from a nightly build). A script is provided that will recreate the xpatch.args file in the current directory:
bash tools/scripts/make_runargs.sh /absolute_path_to/modular-sdk
The following can be used to set up an alias that can be used to launch a JFX application, but using the FX binaries from your development tree. This alias will override the modules built into JDK9.
export JAVA_HOME="path_to_top_of_JDK"
export JFX_BUILD="path_to_top_of_your_repo"
export JFX_PATCH=$JFX_BUILD/build/run.args (or the path to one created by make_runargs.sh)
alias javafx='$JAVA_HOME/bin/java @$JFX_PATCH'
This alias uses the @argfile mechanism to include all that Xpatch/java.library.path verbosity to create a single command to run FX backed by your recently built binaries.
In Windows, the paths for the alias can be a bit tricky to get right, as the JDK wants native Windows paths, and cygwin often works better with a Unix path. Here is an example that works with Cygwin:
export JAVA_HOME=`cygpath -m "/cygdrive/c/Program Files/Java/jdk-9/"`
export JFX_PATCH=`cygpath -m "$JFX_BUILD/build/run.args"`
alias javafx='"$JAVA_HOME/bin/java" @$JFX_PATCH'
Integration with OpenJDK
With the module system in JDK 9 and later, it is not possible to easily overlay an OpenJFX build over an existing JDK as was possible with JDK 8. It is possible to build an OpenJDK that included the updated OpenJFX modules.
To create an integrated OpenJDK with OpenJFX requires two builds:
- OpenJFX for JDK
- OpenJDK, with a configure reference that includes your OpenJFX build.
See the following instructions for building OpenJDK. Use the following repository path: http://hg.openjdk.java.net/jdk/jdk.
Build OpenJFX first.
Configure the JDK with the following addition:
--with-import-modules=_path_to_jfx-dev_/rt/build/modular-sdk
Then build the JDK as normal.
Understanding a JDK Modular world in our developer build
The export of module packages is governed by two sets of files:
- module-info.java, the per module declarations
- module-info.java.extra, fragments of declarations used to augment standard JDK module-info.
During the build process, we generate some files for use by the build, and also by developers working in the sandbox.
- runs.args: for use with the java command, overrides as much as possible the FX modules in the JDK
- must use absolute system paths internally, so cannot be easily copied without editing
- can be rebuilt with tools/scripts/make_runargs.sh
- cannot override with any local changes in module-info, so added packages may need an "--add-exports to be seen.
- does not "re" grant any privileges that our default FX modules have with a security manager
- compile.args: arguments to allow for compile using the sandbox libraries
- must use absolute system paths internally, so cannot be easily copied without editing
- cannot override with any local changes in module-info, so added packages may need an "--add-exports to be seen.
- run.java.policy: a minimum permissions file to use with the security manager.
- intended primarily as a base to start with before adding test specific permissions.
Each of these files has a "test" variant, for example "testrun.args". These files are altered to add in the "shims" version of the module. Note that the build/shims is not populated by the "sdk" task. Use the "copyGeneratedShims" or "test" task.
When dealing primarily with unit tests, additional arguments are needed to access non public API from within the unit tests. These additional arguments have been placed in "addExports" that are local to the tests that need them. For example, "modules/javafx.graphics/src/test/addExports" contains all of the "--add-exports" clauses required to compile and run all of the graphics module junit tests. Care should be taken when modifying these files, as additions may mean that package module-info may need updates too. Keep in mind - if you are adding an "--add-exports" to ALL-UNNAMED so that a junit test can see the API, then the addExports the right place. If you are trying to fix access by another module, it likely is the wrong place.
Adding new packages in a modular world
The JDK Module System adds complexity to the development chain, but particularly when adding new API and especially packages. Adding a new package or changing package visibility will be a multi step task that will require at least two change sets to implement.
Our developer sandbox build uses several items to work around module export during build and testing that you should be familiar with.
Create a "followup JBS" to cover the cleanup/removal of module access workarounds. Be sure to link this new followup JBS to the one you started with.
First Step - development
Modify affected modules module-info to reflect the proposed changes. These changes will only directly affect the current build java compile process. It is key to remember that the java runtime will ignore any changes to module-info, even while it uses "--patch-module".
The next modify buildSrc/addExport files to mirror changes that were made in the module-info files. Mark any additions with a comment containing the "Completion JBS" number, like this:
# to be removed by 81XXXXX
--add-exports=javafx.graphics/com.sun.javafx.newpackage=javafx.controls
--add-exports=javafx.graphics/com.sun.javafx.newpackage=ALL-UNNAMED
Note, if you add a junit test that for the new package, you will likely also need an export to ALL-UNNAMED (which the junit jar is a member of). The result may be two exports in buildSrc/addExport to add the temporary workarounds required for both development and test. If you are not modifying unit tests - do not add the ALL-UNNAMED line.
Complete development of your new package and adding unit test coverage, and all of the other process we normally do.
Your complete change set will now contain all of the delta required for the nightly build and test your changes. The promotion process will soon merge your module-info changes into the JDK. Once there is a promoted JDK that has the new module-info changes, it is possible to move to the second step.
One consideration - building a local development copy of the JDK is not difficult. In some cases, it may be useful to create a local developer JDK that incorporates the module-info changes, even before development of the changeset it complete. This developer JDK will honor the new package exports without the need of the changes to the addExport files. Note however, your change set may break the build if it has not be tested with the current minimum promoted JDK build.
Second Step - cleanup
Once the changes are promoted into a JDK, the second step to remove the addExports workarounds can be scheduled with the team lead.
As both the build machine and the other developers will need to update to the newer JDK build, this step will need to be coordinated.
Create a change set with:
- the now unneeded addExport lines removed
- the minimum JDK version used by the build has been updated to the new minimum
Test, review and commit as normal.