Skip to content

Latest commit

 

History

History
138 lines (114 loc) · 6.71 KB

README.md

File metadata and controls

138 lines (114 loc) · 6.71 KB

Native Image

GraalVM Native Image allows to ahead-of-time compile Java code to a standalone executable, called a native image. This executable includes the application classes, classes from its dependencies, runtime library classes from JDK and statically linked native code from JDK. It does not run on the Java VM, but includes necessary components like memory management and thread scheduling from a different virtual machine, called "Substrate VM". Substrate VM is the name for the runtime components (like the deoptimizer, garbage collector, thread scheduling etc.). The resulting program has faster startup time and lower runtime memory overhead compared to a Java VM.

The Native Image builder or native-image is a utility that processes all the classes of your application and their dependencies, including those from the JDK. It analyses these classes to determine which classes, methods and fields are reachable during application execution. It then ahead-of-time compiles all reachable code and data into a native executable for a specific operating system and architecture. This entire process is called image build time to clearly distinguish it from the compilation of Java source code to bytecode.

GraalVM Native Image supports JVM-based languages, e.g., Java, Scala, Clojure, Kotlin. The resulting native image can, optionally, execute dynamic languages like JavaScript, Ruby, R or Python. Polyglot embeddings can also be compiled ahead-of-time. To inform native-image of guest languages used by an application, specify --language:<languageId> for each guest language used (e.g., --language:js).

License

GraalVM Native Image is licensed under the GPL 2 with Classpath Exception.

Install Native Image

Native Image is distributed as a separate installable and can be added to the core installation with the GraalVM Updater tool.

If you use GraalVM, run this command to install Native Image from GitHub:

gu install native-image

After this additional step, the native-image executable will become available in the bin directory.

Take a look at the native image generation or compiling a Java and Kotlin app ahead-of-time samples.

Prerequisites

For compilation native-image depends on the local toolchain. Install glibc-devel, zlib-devel (header files for the C library and zlib) and gcc, using a package manager available on your OS. Some Linux distributions may additionally require libstdc++-static.

On Oracle Linux use yum package manager:

sudo yum install gcc glibc-devel zlib-devel

You can still install libstdc++-static as long as the optional repositories are enabled (ol7_optional_latest on Oracle Linux 7 and ol8_codeready_builder on Oracle Linux 8).

On Ubuntu Linux use apt-get package manager:

sudo apt-get install build-essential libz-dev zlib1g-dev

On other Linux distributions use dnf package manager:

sudo dnf install gcc glibc-devel zlib-devel libstdc++-static

On macOS use xcode:

xcode-select --install

Prerequisites for Using Native Image on Windows

To make use of Native Image on Windows, follow the further recommendations. The required Microsoft Visual C++ (MSVC) version depends on the JDK version that GraalVM is based on. For GraalVM distribution based on JDK 8, you will need MSVC 2010 SP1 version. The recommended installation method is using Microsoft Windows SDK 7.1:

  1. Download the SDK file GRMSDKX_EN_DVD.iso for from Microsoft.
  2. Mount the image by opening F:\Setup\SDKSetup.exe directly.

For GraalVM distribution based on JDK 11, you will need MSVC 2017 15.5.5 or later version.

The last prerequisite, common for both GraalVM distribution based on JDK 11 and JDK 8, is the proper Developer Command Prompt for your version of Visual Studio. On Windows the native-image tool only works when it is executed from the x64 Native Tools Command Prompt.

How to Determine What Version of GraalVM an Image Is Generated With?

Assuming you have a Java class file EmptyHello.class containing an empty main method and have generated an empty shared object emptyhello with GraalVM Native Image Generator utility of it:

native-image -cp hello EmptyHello
[emptyhello:11228]    classlist:     149.59 ms
...

If you do not know what GraalVM distribution is set to the PATH environment variable, how to determine if a native image was compiled with Community or Enterprise Edition? Run this command:

strings emptyhello | grep com.oracle.svm.core.VM

The expected output should match the following:

com.oracle.svm.core.VM GraalVM 20.2.0 Java 11 EE

Note: Python source code or LLVM bitcode interpreted or compiled with GraalVM Community Edition will not have the same security characteristics as the same code interpreted or compiled using GraalVM Enterprise Edition. There is a GraalVM string embedded in each image that allows to figure out the version and variant of the base (Community or Enterprise) used to build an image. The following command will query that information from an image:

strings <path to native-image exe or shared object> | grep com.oracle.svm.core.VM

Here is an example output:

com.oracle.svm.core.VM.Target.LibC=com.oracle.svm.core.posix.linux.libc.GLibC
com.oracle.svm.core.VM.Target.Platform=org.graalvm.nativeimage.Platform$LINUX_AMD64
com.oracle.svm.core.VM.Target.StaticLibraries=liblibchelper.a|libnet.a|libffi.a|libextnet.a|libnio.a|libjava.a|libfdlibm.a|libzip.a|libjvm.a
com.oracle.svm.core.VM=GraalVM 20.2.0 Java 11
com.oracle.svm.core.VM.Target.Libraries=pthread|dl|z|rt
com.oracle.svm.core.VM.Target.CCompiler=gcc|redhat|x86_64|10.2.1

If the image was build with Oracle GraalVM Enterprise Edition the output would instead contain:

com.oracle.svm.core.VM=GraalVM 20.2.0 Java 11 EE

Ahead-of-time Compilation Limitations

There is a small portion of Java features are not susceptible to ahead-of-time compilation, and will therefore miss out on the performance advantages. To be able to build a highly optimized native executable, GraalVM runs an aggressive static analysis that requires a closed-world assumption, which means that all classes and all bytecodes that are reachable at run time must be known at build time. Therefore, it is not possible to load new data that have not been available during ahead-of-time compilation. Continue reading to the GraalVM Native Image Compatibility and Optimization Guide.