The GraalVM compiler is a dynamic compiler written in Java that integrates with the HotSpot JVM. It has a focus on high performance and extensibility. In addition, it provides optimized performance for languages implemented with Truffle Framework-based languages running on the JVM. For brevity, the GraalVM compiler is often referred to as "the compiler" below.
Working with the GraalVM compiler will mean cloning more than one repository and so it's recommended to create and use a separate directory:
mkdir graal
cd graal
To simplify development, a separate Python tool called mx has been co-developed. This tool must be downloaded and put onto your PATH:
git clone https://github.com/graalvm/mx.git
export PATH=$PWD/mx:$PATH
The compiler depends on a JDK that supports a compatible version of JVMCI (JVM Compiler Interface). There is a JVMCI port for JDK 8 and the required JVMCI version is built into the JDK as of JDK 11. A JVMCI-enabled JDK 8 can be downloaded from GitHub or you can build it yourself.
Most compiler sources are compliant with Java 8. Some sources use API specific to JDK 8 or only introduced in JDK 9. These sources are in versioned projects. If you don't have a JDK that satisfies the requirement of a versioned project, the project is ignored by mx.
If you want to develop on a single JDK version, you only need to define JAVA_HOME. For example:
export JAVA_HOME=/usr/lib/jvm/oraclejdk1.8.0_212-jvmci-20-b01
or:
export JAVA_HOME=/usr/lib/jvm/jdk-11
If you want to ensure your changes will pass both JDK 8 and JDK 11 gates, you can specify the secondary JDK(s) in EXTRA_JAVA_HOMES.
For example, to develop for JDK 8 while ensuring mx build still works with the JDK 11 specific sources:
export JAVA_HOME=/usr/lib/jvm/oraclejdk1.8.0_212-jvmci-20-b01
export EXTRA_JAVA_HOMES=/usr/lib/jvm/jdk-11
And on macOS:
export JAVA_HOME=/Library/Java/JavaVirtualMachines/oraclejdk1.8.0_212-jvmci-20-b01/Contents/Home
export EXTRA_JAVA_HOMES=/Library/Java/JavaVirtualMachines/jdk-11.jdk/Contents/Home
If you omit EXTRA_JAVA_HOMES in the above examples, versioned projects depending on the specified JDK(s) will be ignored.
Note that JAVA_HOME defines the primary JDK for development. For instance, when running mx vm, this is the JDK that will be used so if you want to run on JDK 11, swap JDK 8 and JDK 11 in JAVA_HOME and EXTRA_JAVA_HOMES.
Now change to the graal/compiler directory:
cd graal/compiler
Changing to the graal/compiler directory informs mx that the focus of development (called the primary suite) is the GraalVM compiler.
All subsequent mx commands should be executed from this directory.
Here's the recipe for building and running the GraalVM compiler:
mx build
mx vm
By default, the GraalVM compiler is only used for hosted compilation (i.e., the VM still uses C2 for compilation).
To make the VM use the GraalVM compiler as the top tier JIT compiler, add the -XX:+UseJVMCICompiler option to the command line.
To disable use of the GraalVM compiler altogether, use -XX:-EnableJVMCI.
When applying above steps on Windows, replace export with set.
You can generate IDE project configurations by running:
mx ideinit
This will generate Eclipse, IntelliJ, and NetBeans project configurations. Further information on how to import these project configurations into individual IDEs can be found on the IDEs page.
The Ideal Graph Visualizer(IGV) is very useful in terms of visualizing the compiler's intermediate representation (IR). IGV is available on OTN. You can get a quick insight into this tool by running the commands below. The first command launches the tool and the second runs one of the unit tests included in the code base with extra options to dump the compiler IR for all methods compiled. You should wait for the GUI to appear before running the second command.
$GRAALVM_EE_HOME/bin/idealgraphvisualizer &
mx unittest -Dgraal.Dump BC_athrow0
If you added -XX:+UseJVMCICompiler as described above, you will see IR for compilations requested by the VM itself in addition to compilations requested by the unit test.
The former are those with a prefix in the UI denoting the compiler thread and id of the compilation (e.g., JVMCI CompilerThread0:390).
Further information can be found on the Debugging page.
Building the GraalVM compiler as described above means it is executed in the same way as any other Java code in the VM; it allocates in the HotSpot heap and it starts execution in the interpreter with hot parts being subsequently JIT compiled. The advantage of this mode is that it can be debugged with a Java debugger.
However, it has some disadvantages. Firstly, since it uses the object heap, it can
reduce application object locality and increase GC pause times. Additionally, it can
complicate fine tuning options such as -Xmx and -Xms which now need to take the
heap usage of the compiler into account. Secondly, the compiler will initially be executed
in the interpreter and only get faster over time as its hot methods are JIT
compiled. This is mitigated to some degree by forcing the GraalVM compiler
to only be compiled by C1 (i.e., -Dgraal.CompileGraalWithC1Only=true) but this comes at the cost
of slower compilation speed.
To address these issues, the GraalVM compiler can be deployed as a native shared library. The shared library is a native image produced using SubstrateVM. In this mode, the GraalVM compiler uses memory separate from the HotSpot heap and it runs compiled from the start. That is, it has execution properties similar to other native HotSpot compilers such as C1 and C2.
To build libgraal:
cd graal/vm
mx --env libgraal build
The newly built GraalVM image containing libgraal is available at:
mx --env libgraal graalvm-home
or following this symlink:
./latest_graalvm_home
For more information about building GraalVM images, see the README file of the vm suite.
Without leaving the graal/vm directory, you can now run libgraal as follows:
-
Use the GraalVM image that you just built:
./latest_graalvm_home/bin/java -XX:+UseJVMCICompiler -XX:+UseJVMCINativeLibrary ... -
Use
mx:- On linux:
mx -p ../compiler vm -XX:JVMCILibPath=latest_graalvm_home/jre/lib/amd64 -XX:+UseJVMCICompiler -XX:+UseJVMCINativeLibrary ... - On macOS:
mx -p ../compiler vm -XX:JVMCILibPath=latest_graalvm_home/jre/lib -XX:+UseJVMCICompiler -XX:+UseJVMCINativeLibrary ...
- On linux:
For video tutorials, presentations and publications on the GraalVM compiiler visit the Publications page.
To create a JVMCI enabled JDK 8 on other platforms (e.g., Windows):
git clone https://github.com/graalvm/graal-jvmci-8
cd graal-jvmci-8
mx --java-home /path/to/jdk8 build
mx --java-home /path/to/jdk8 unittest
export JAVA_HOME=$(mx --java-home /path/to/jdk8 jdkhome)
You need to use the same JDK the GitHub downloads are based on as the argument to --java-home in the above commands.
The build step above should work on all supported JDK 8 build platforms.
It should also work on other platforms (such as Oracle Linux, CentOS and Fedora as described here).
If you run into build problems, send a message to http://mail.openjdk.java.net/mailman/listinfo/graal-dev.
Building JDK requires some bash-like environment. Fortunately, the one that comes as a part of the standard
Git for Windows installation will suffice, in which case you will just have to set MKS_HOME to point
to the directory with Linux tools, e.g.:
set MKS_HOME=<GIT_DIR>\usr\bin
where <GIT_DIR> is a path to your Git installation directory. It is important that there are NO
spaces in the path, otherwise the build will fail.
You will also need an MSVC 2010 SP1 compiler. The following tool chain is recommended:
- Microsoft Windows SDK for Windows 7 and .NET Framework 4 (ISO)
- Microsoft Visual C++ 2010 Service Pack 1 Compiler Update for the Windows SDK 7.1
The GraalVM compiler is licensed under the GPL 2.