OpenJDK

OpenJDK


Introduction

This README file contains build instructions for the OpenJDK. Building the source code for the OpenJDK requires a certain degree of technical expertise.

!!!!!!!!!!!!!!! THIS IS A MAJOR RE-WRITE of this document. !!!!!!!!!!!!!

Some Headlines:


Contents



Use of Mercurial

The OpenJDK sources are maintained with the revision control system Mercurial. If you are new to Mercurial, please see the Beginner Guides or refer to the Mercurial Book. The first few chapters of the book provide an excellent overview of Mercurial, what it is and how it works.

For using Mercurial with the OpenJDK refer to the Developer Guide: Installing and Configuring Mercurial section for more information.

Getting the Source

To get the entire set of OpenJDK Mercurial repositories use the script get_source.sh located in the root repository:

  hg clone http://hg.openjdk.java.net/jdk9/jdk9 YourOpenJDK
  cd YourOpenJDK
  bash ./get_source.sh

Once you have all the repositories, keep in mind that each repository is its own independent repository. You can also re-run ./get_source.sh anytime to pull over all the latest changesets in all the repositories. This set of nested repositories has been given the term "forest" and there are various ways to apply the same hg command to each of the repositories. For example, the script make/scripts/hgforest.sh can be used to repeat the same hg command on every repository, e.g.

  cd YourOpenJDK
  bash ./make/scripts/hgforest.sh status

Repositories

The set of repositories and what they contain:

Repository Source Guidelines

There are some very basic guidelines:


Building

The very first step in building the OpenJDK is making sure the system itself has everything it needs to do OpenJDK builds. Once a system is setup, it generally doesn't need to be done again.

Building the OpenJDK is now done with running a configure script which will try and find and verify you have everything you need, followed by running make, e.g.

bash ./configure
make all

Where possible the configure script will attempt to located the various components in the default locations or via component specific variable settings. When the normal defaults fail or components cannot be found, additional configure options may be necessary to help configure find the necessary tools for the build, or you may need to re-visit the setup of your system due to missing software packages.

NOTE: The configure script file does not have execute permissions and will need to be explicitly run with bash, see the source guidelines.


System Setup

Before even attempting to use a system to build the OpenJDK there are some very basic system setups needed. For all systems:

* Install a Bootstrap JDK. All OpenJDK builds require access to a previously released JDK called the bootstrap JDK or boot JDK. The general rule is that the bootstrap JDK must be an instance of the previous major release of the JDK. In addition, there may be a requirement to use a release at or beyond a particular update level.

Building JDK 9 requires JDK 8. JDK 9 developers should not use JDK 9 as the boot JDK, to ensure that JDK 9 dependencies are not introduced into the parts of the system that are built with JDK 8.

The JDK 8 binaries can be downloaded from Oracle's JDK 8 download site. For build performance reasons it is very important that this bootstrap JDK be made available on the local disk of the machine doing the build. You should add its bin directory to the PATH environment variable. If configure has any issues finding this JDK, you may need to use the configure option --with-boot-jdk.

And for specific systems:

Install all the software development packages needed including alsa, freetype, cups, and xrender. See specific system packages.

Install all the software development packages needed including Studio Compilers, freetype, cups, and xrender. See specific system packages.

Install XCode 6.3

Linux

With Linux, try and favor the system packages over building your own or getting packages from other areas. Most Linux builds should be possible with the system's available packages.

Note that some Linux systems have a habit of pre-populating your environment variables for you, for example JAVA_HOME might get pre-defined for you to refer to the JDK installed on your Linux system. You will need to unset JAVA_HOME. It's a good idea to run env and verify the environment variables you are getting from the default system settings make sense for building the OpenJDK.

Solaris

Studio Compilers

At a minimum, the Studio 12 Update 4 Compilers (containing version 5.13 of the C and C++ compilers) is required, including specific patches.

The Solaris Studio installation should contain at least these packages:

Package Version
developer/solarisstudio-124/backend 12.4-1.0.6.0
developer/solarisstudio-124/c++ 12.4-1.0.10.0
developer/solarisstudio-124/cc 12.4-1.0.4.0
developer/solarisstudio-124/library/c++-libs 12.4-1.0.10.0
developer/solarisstudio-124/library/math-libs 12.4-1.0.0.1
developer/solarisstudio-124/library/studio-gccrt 12.4-1.0.0.1
developer/solarisstudio-124/studio-common 12.4-1.0.0.1
developer/solarisstudio-124/studio-ja 12.4-1.0.0.1
developer/solarisstudio-124/studio-legal 12.4-1.0.0.1
developer/solarisstudio-124/studio-zhCN 12.4-1.0.0.1

In particular backend 12.4-1.0.6.0 contains a critical patch for the sparc version.

Place the bin directory in PATH.

The Oracle Solaris Studio Express compilers at: Oracle Solaris Studio Express Download site are also an option, although these compilers have not been extensively used yet.

Windows

Windows Unix Toolkit

Building on Windows requires a Unix-like environment, notably a Unix-like shell. There are several such environments available of which Cygwin and MinGW/MSYS are currently supported for the OpenJDK build. One of the differences of these systems from standard Windows tools is the way they handle Windows path names, particularly path names which contain spaces, backslashes as path separators and possibly drive letters. Depending on the use case and the specifics of each environment these path problems can be solved by a combination of quoting whole paths, translating backslashes to forward slashes, escaping backslashes with additional backslashes and translating the path names to their "8.3" version.

CYGWIN

CYGWIN is an open source, Linux-like environment which tries to emulate a complete POSIX layer on Windows. It tries to be smart about path names and can usually handle all kinds of paths if they are correctly quoted or escaped although internally it maps drive letters <drive>: to a virtual directory /cygdrive/<drive>.

You can always use the cygpath utility to map pathnames with spaces or the backslash character into the C:/ style of pathname (called 'mixed'), e.g. cygpath -s -m "<path>".

Note that the use of CYGWIN creates a unique problem with regards to setting PATH. Normally on Windows the PATH variable contains directories separated with the ";" character (Solaris and Linux use ":"). With CYGWIN, it uses ":", but that means that paths like "C:/path" cannot be placed in the CYGWIN version of PATH and instead CYGWIN uses something like /cygdrive/c/path which CYGWIN understands, but only CYGWIN understands.

The OpenJDK build requires CYGWIN version 1.7.16 or newer. Information about CYGWIN can be obtained from the CYGWIN website at www.cygwin.com.

By default CYGWIN doesn't install all the tools required for building the OpenJDK. Along with the default installation, you need to install the following tools.

Binary Name Category Package Description
ar.exe Devel binutils The GNU assembler, linker and binary utilities
make.exe Devel make The GNU version of the 'make' utility built for CYGWIN
m4.exe Interpreters m4 GNU implementation of the traditional Unix macro processor
cpio.exe Utils cpio A program to manage archives of files
gawk.exe Utils awk Pattern-directed scanning and processing language
file.exe Utils file Determines file type using 'magic' numbers
zip.exe Archive zip Package and compress (archive) files
unzip.exe Archive unzip Extract compressed files in a ZIP archive
free.exe System procps Display amount of free and used memory in the system

Note that the CYGWIN software can conflict with other non-CYGWIN software on your Windows system. CYGWIN provides a FAQ for known issues and problems, of particular interest is the section on BLODA (applications that interfere with CYGWIN).

MinGW/MSYS

MinGW ("Minimalist GNU for Windows") is a collection of free Windows specific header files and import libraries combined with GNU toolsets that allow one to produce native Windows programs that do not rely on any 3rd-party C runtime DLLs. MSYS is a supplement to MinGW which allows building applications and programs which rely on traditional UNIX tools to be present. Among others this includes tools like bash and make. See MinGW/MSYS for more information.

Like Cygwin, MinGW/MSYS can handle different types of path formats. They are internally converted to paths with forward slashes and drive letters <drive>: replaced by a virtual directory /<drive>. Additionally, MSYS automatically detects binaries compiled for the MSYS environment and feeds them with the internal, Unix-style path names. If native Windows applications are called from within MSYS programs their path arguments are automatically converted back to Windows style path names with drive letters and backslashes as path separators. This may cause problems for Windows applications which use forward slashes as parameter separator (e.g. cl /nologo /I) because MSYS may wrongly replace such parameters by drive letters.

In addition to the tools which will be installed by default, you have to manually install the msys-zip and msys-unzip packages. This can be easily done with the MinGW command line installer:

  mingw-get.exe install msys-zip
  mingw-get.exe install msys-unzip
Visual Studio 2013 Compilers

The 32-bit and 64-bit OpenJDK Windows build requires Microsoft Visual Studio C++ 2013 (VS2013) Professional Edition or Express compiler. The compiler and other tools are expected to reside in the location defined by the variable VS120COMNTOOLS which is set by the Microsoft Visual Studio installer.

Only the C++ part of VS2013 is needed. Try to let the installation go to the default install directory. Always reboot your system after installing VS2013. The system environment variable VS120COMNTOOLS should be set in your environment.

Make sure that TMP and TEMP are also set in the environment and refer to Windows paths that exist, like C:\temp, not /tmp, not /cygdrive/c/temp, and not C:/temp. C:\temp is just an example, it is assumed that this area is private to the user, so by default after installs you should see a unique user path in these variables.

Mac OS X

Make sure you get the right XCode version.


Configure

The basic invocation of the configure script looks like:

bash ./configure [options]

This will create an output directory containing the "configuration" and setup an area for the build result. This directory typically looks like:

build/linux-x64-normal-server-release

configure will try to figure out what system you are running on and where all necessary build components are. If you have all prerequisites for building installed, it should find everything. If it fails to detect any component automatically, it will exit and inform you about the problem. When this happens, read more below in the configure options.

Some examples:

Windows 32bit build with freetype specified:
bash ./configure --with-freetype=/cygdrive/c/freetype-i586 --with-target-bits=32

Debug 64bit Build:
bash ./configure --enable-debug --with-target-bits=64

Configure Options

Complete details on all the OpenJDK configure options can be seen with:

bash ./configure --help=short

Use -help to see all the configure options available. You can generate any number of different configurations, e.g. debug, release, 32, 64, etc.

Some of the more commonly used configure options are:

--enable-debug
set the debug level to fastdebug (this is a shorthand for --with-debug-level=fastdebug)

--with-alsa=path
select the location of the Advanced Linux Sound Architecture (ALSA)

Version 0.9.1 or newer of the ALSA files are required for building the OpenJDK on Linux. These Linux files are usually available from an "alsa" of "libasound" development package, and it's highly recommended that you try and use the package provided by the particular version of Linux that you are using.

--with-boot-jdk=path
select the Bootstrap JDK

--with-boot-jdk-jvmargs="args"
provide the JVM options to be used to run the Bootstrap JDK

--with-cacerts=path
select the path to the cacerts file.

See Certificate Authority on Wikipedia for a better understanding of the Certificate Authority (CA). A certificates file named "cacerts" represents a system-wide keystore with CA certificates. In JDK and JRE binary bundles, the "cacerts" file contains root CA certificates from several public CAs (e.g., VeriSign, Thawte, and Baltimore). The source contain a cacerts file without CA root certificates. Formal JDK builders will need to secure permission from each public CA and include the certificates into their own custom cacerts file. Failure to provide a populated cacerts file will result in verification errors of a certificate chain during runtime. By default an empty cacerts file is provided and that should be fine for most JDK developers.

--with-cups=path
select the CUPS install location

The Common UNIX Printing System (CUPS) Headers are required for building the OpenJDK on Solaris and Linux. The Solaris header files can be obtained by installing the package print/cups.

The CUPS header files can always be downloaded from www.cups.org.

--with-cups-include=path
select the CUPS include directory location

--with-debug-level=level
select the debug information level of release, fastdebug, or slowdebug

--with-dev-kit=path
select location of the compiler install or developer install location

--with-freetype=path
select the freetype files to use.

Expecting the freetype libraries under lib/ and the headers under include/.

Version 2.3 or newer of FreeType is required. On Unix systems required files can be available as part of your distribution (while you still may need to upgrade them). Note that you need development version of package that includes both the FreeType library and header files.

You can always download latest FreeType version from the FreeType website. Building the freetype 2 libraries from scratch is also possible, however on Windows refer to the Windows FreeType DLL build instructions.

Note that by default FreeType is built with byte code hinting support disabled due to licensing restrictions. In this case, text appearance and metrics are expected to differ from Sun's official JDK build. See the SourceForge FreeType2 Home Page for more information.

--with-import-hotspot=path
select the location to find hotspot binaries from a previous build to avoid building hotspot

--with-target-bits=arg
select 32 or 64 bit build

--with-jvm-variants=variants
select the JVM variants to build from, comma separated list that can include: server, client, kernel, zero and zeroshark

--with-memory-size=size
select the RAM size that GNU make will think this system has

--with-msvcr-dll=path
select the msvcr100.dll file to include in the Windows builds (C/C++ runtime library for Visual Studio).

This is usually picked up automatically from the redist directories of Visual Studio 2013.

--with-num-cores=cores
select the number of cores to use (processor count or CPU count)

--with-x=path
select the location of the X11 and xrender files.

The XRender Extension Headers are required for building the OpenJDK on Solaris and Linux. The Linux header files are usually available from a "Xrender" development package, it's recommended that you try and use the package provided by the particular distribution of Linux that you are using. The Solaris XRender header files is included with the other X11 header files in the package SFWxwinc on new enough versions of Solaris and will be installed in /usr/X11/include/X11/extensions/Xrender.h or /usr/openwin/share/include/X11/extensions/Xrender.h


Make

The basic invocation of the make utility looks like:

make all

This will start the build to the output directory containing the "configuration" that was created by the configure script. Run make help for more information on the available targets.

There are some of the make targets that are of general interest:

empty
build everything but no images

all
build everything including images

all-conf
build all configurations

images
create complete j2sdk and j2re images

install
install the generated images locally, typically in /usr/local

clean
remove all files generated by make, but not those generated by configure

dist-clean
remove all files generated by both and configure (basically killing the configuration)

help
give some help on using make, including some interesting make targets


Testing

When the build is completed, you should see the generated binaries and associated files in the j2sdk-image directory in the output directory. In particular, the build/*/images/j2sdk-image/bin directory should contain executables for the OpenJDK tools and utilities for that configuration. The testing tool jtreg will be needed and can be found at: the jtreg site. The provided regression tests in the repositories can be run with the command:

cd test && make PRODUCT_HOME=`pwd`/../build/*/images/j2sdk-image all


Appendix A: Hints and Tips

FAQ

Q: The generated-configure.sh file looks horrible! How are you going to edit it?
A: The generated-configure.sh file is generated (think "compiled") by the autoconf tools. The source code is in configure.ac and various .m4 files in common/autoconf, which are much more readable.

Q: Why is the generated-configure.sh file checked in, if it is generated?
A: If it was not generated, every user would need to have the autoconf tools installed, and re-generate the configure file as the first step. Our goal is to minimize the work needed to be done by the user to start building OpenJDK, and to minimize the number of external dependencies required.

Q: Do you require a specific version of autoconf for regenerating generated-configure.sh?
A: Yes, version 2.69 is required and should be easy enough to aquire on all supported operating systems. The reason for this is to avoid large spurious changes in generated-configure.sh.

Q: How do you regenerate generated-configure.sh after making changes to the input files?
A: Regnerating generated-configure.sh should always be done using the script common/autoconf/autogen.sh to ensure that the correct files get updated. This script should also be run after mercurial tries to merge generated-configure.sh as a merge of the generated file is not guaranteed to be correct.

Q: What are the files in common/makefiles/support/* for? They look like gibberish.
A: They are a somewhat ugly hack to compensate for command line length limitations on certain platforms (Windows, Solaris). Due to a combination of limitations in make and the shell, command lines containing too many files will not work properly. These helper files are part of an elaborate hack that will compress the command line in the makefile and then uncompress it safely. We're not proud of it, but it does fix the problem. If you have any better suggestions, we're all ears! :-)

Q: I want to see the output of the commands that make runs, like in the old build. How do I do that?
A: You specify the LOG variable to make. There are several log levels:

Q: When do I have to re-run configure?
A: Normally you will run configure only once for creating a configuration. You need to re-run configuration only if you want to change any configuration options, or if you pull down changes to the configure script.

Q: I have added a new source file. Do I need to modify the makefiles?
A: Normally, no. If you want to create e.g. a new native library, you will need to modify the makefiles. But for normal file additions or removals, no changes are needed. There are certan exceptions for some native libraries where the source files are spread over many directories which also contain sources for other libraries. In these cases it was simply easier to create include lists rather than excludes.

Q: When I run configure --help, I see many strange options, like --dvidir. What is this?
A: Configure provides a slew of options by default, to all projects that use autoconf. Most of them are not used in OpenJDK, so you can safely ignore them. To list only OpenJDK specific features, use configure --help=short instead.

Q: configure provides OpenJDK-specific features such as --with-builddeps-server that are not described in this document. What about those?
A: Try them out if you like! But be aware that most of these are experimental features. Many of them don't do anything at all at the moment; the option is just a placeholder. Others depend on pieces of code or infrastructure that is currently not ready for prime time.

Q: How will you make sure you don't break anything?
A: We have a script that compares the result of the new build system with the result of the old. For most part, we aim for (and achieve) byte-by-byte identical output. There are however technical issues with e.g. native binaries, which might differ in a byte-by-byte comparison, even when building twice with the old build system. For these, we compare relevant aspects (e.g. the symbol table and file size). Note that we still don't have 100% equivalence, but we're close.

Q: I noticed this thing X in the build that looks very broken by design. Why don't you fix it?
A: Our goal is to produce a build output that is as close as technically possible to the old build output. If things were weird in the old build, they will be weird in the new build. Often, things were weird before due to obscurity, but in the new build system the weird stuff comes up to the surface. The plan is to attack these things at a later stage, after the new build system is established.

Q: The code in the new build system is not that well-structured. Will you fix this?
A: Yes! The new build system has grown bit by bit as we converted the old system. When all of the old build system is converted, we can take a step back and clean up the structure of the new build system. Some of this we plan to do before replacing the old build system and some will need to wait until after.

Q: Is anything able to use the results of the new build's default make target?
A: Yes, this is the minimal (or roughly minimal) set of compiled output needed for a developer to actually execute the newly built JDK. The idea is that in an incremental development fashion, when doing a normal make, you should only spend time recompiling what's changed (making it purely incremental) and only do the work that's needed to actually run and test your code. The packaging stuff that is part of the images target is not needed for a normal developer who wants to test his new code. Even if it's quite fast, it's still unnecessary. We're targeting sub-second incremental rebuilds! ;-) (Or, well, at least single-digit seconds...)

Q: I usually set a specific environment variable when building, but I can't find the equivalent in the new build. What should I do?
A: It might very well be that we have neglected to add support for an option that was actually used from outside the build system. Email us and we will add support for it!

Build Performance Tips

Building OpenJDK requires a lot of horsepower. Some of the build tools can be adjusted to utilize more or less of resources such as parallel threads and memory. The configure script analyzes your system and selects reasonable values for such options based on your hardware. If you encounter resource problems, such as out of memory conditions, you can modify the detected values with:

It might also be necessary to specify the JVM arguments passed to the Bootstrap JDK, using e.g. --with-boot-jdk-jvmargs="-Xmx8G -enableassertions". Doing this will override the default JVM arguments passed to the Bootstrap JDK.

One of the top goals of the new build system is to improve the build performance and decrease the time needed to build. This will soon also apply to the java compilation when the Smart Javac wrapper is fully supported.

At the end of a successful execution of configure, you will get a performance summary, indicating how well the build will perform. Here you will also get performance hints. If you want to build fast, pay attention to those!

Building with ccache

The OpenJDK build supports building with ccache when using gcc or clang. Using ccache can radically speed up compilation of native code if you often rebuild the same sources. Your milage may vary however so we recommend evaluating it for yourself. To enable it, make sure it's on the path and configure with --enable-ccache.

Building on local disk

If you are using network shares, e.g. via NFS, for your source code, make sure the build directory is situated on local disk. The performance penalty is extremely high for building on a network share, close to unusable.

Building only one JVM

The old build builds multiple JVMs on 32-bit systems (client and server; and on Windows kernel as well). In the new build we have changed this default to only build server when it's available. This improves build times for those not interested in multiple JVMs. To mimic the old behavior on platforms that support it, use --with-jvm-variants=client,server.

Selecting the number of cores to build on

By default, configure will analyze your machine and run the make process in parallel with as many threads as you have cores. This behavior can be overridden, either "permanently" (on a configure basis) using --with-num-cores=N or for a single build only (on a make basis), using make JOBS=N.

If you want to make a slower build just this time, to save some CPU power for other processes, you can run e.g. make JOBS=2. This will force the makefiles to only run 2 parallel processes, or even make JOBS=1 which will disable parallelism.

If you want to have it the other way round, namely having slow builds default and override with fast if you're impatient, you should call configure with --with-num-cores=2, making 2 the default. If you want to run with more cores, run make JOBS=8

Troubleshooting

Solving build problems

If the build fails (and it's not due to a compilation error in a source file you've changed), the first thing you should do is to re-run the build with more verbosity. Do this by adding LOG=debug to your make command line.

The build log (with both stdout and stderr intermingled, basically the same as you see on your console) can be found as build.log in your build directory.

You can ask for help on build problems with the new build system on either the build-dev or the build-infra-dev mailing lists. Please include the relevant parts of the build log.

A build can fail for any number of reasons. Most failures are a result of trying to build in an environment in which all the pre-build requirements have not been met. The first step in troubleshooting a build failure is to recheck that you have satisfied all the pre-build requirements for your platform. Scanning the configure log is a good first step, making sure that what it found makes sense for your system. Look for strange error messages or any difficulties that configure had in finding things.

Some of the more common problems with builds are briefly described below, with suggestions for remedies.

Creating the javadocs can be very slow, if you are running javadoc, consider skipping that step.

Faster CPUs, more RAM, and a faster DISK usually helps. The VM build tends to be CPU intensive (many C++ compiles), and the rest of the JDK will often be disk intensive.

Faster compiles are possible using a tool called ccache.

Warning message: File 'xxx' has modification time in the future.
Warning message: Clock skew detected. Your build may be incomplete.

These warnings can occur when the clock on the build machine is out of sync with the timestamps on the source files. Other errors, apparently unrelated but in fact caused by the clock skew, can occur along with the clock skew warnings. These secondary errors may tend to obscure the fact that the true root cause of the problem is an out-of-sync clock.

If you see these warnings, reset the clock on the build machine, run "gmake clobber" or delete the directory containing the build output, and restart the build from the beginning.

make JOBS=1

to reduce the load on the system.

To completely disable SELinux:

  1. $ su root
  2. # system-config-securitylevel
  3. In the window that appears, select the SELinux tab
  4. Disable SELinux

Alternatively, instead of completely disabling it you could disable just this one check.

  1. Select System->Administration->SELinux Management
  2. In the SELinux Management Tool which appears, select "Boolean" from the menu on the left
  3. Expand the "Memory Protection" group
  4. Check the first item, labeled "Allow all unconfined executables to use libraries requiring text relocation ..."

The CYGWIN software can conflict with other non-CYGWIN software. See the CYGWIN FAQ section on BLODA (applications that interfere with CYGWIN).


Appendix B: GNU make

The Makefiles in the OpenJDK are only valid when used with the GNU version of the utility command make (usually called gmake on Solaris). A few notes about using GNU make:

Information on GNU make, and access to ftp download sites, are available on the GNU make web site. The latest source to GNU make is available at ftp.gnu.org/pub/gnu/make/.

Building GNU make

First step is to get the GNU make 3.81 or newer source from ftp.gnu.org/pub/gnu/make/. Building is a little different depending on the OS but is basically done with:

  bash ./configure
  make

Appendix C: Build Environments

Minimum Build Environments

This file often describes specific requirements for what we call the "minimum build environments" (MBE) for this specific release of the JDK. What is listed below is what the Oracle Release Engineering Team will use to build the Oracle JDK product. Building with the MBE will hopefully generate the most compatible bits that install on, and run correctly on, the most variations of the same base OS and hardware architecture. In some cases, these represent what is often called the least common denominator, but each Operating System has different aspects to it.

In all cases, the Bootstrap JDK version minimum is critical, we cannot guarantee builds will work with older Bootstrap JDK's. Also in all cases, more RAM and more processors is better, the minimums listed below are simply recommendations.

With Solaris and Mac OS X, the version listed below is the oldest release we can guarantee builds and works, and the specific version of the compilers used could be critical.

With Windows the critical aspect is the Visual Studio compiler used, which due to it's runtime, generally dictates what Windows systems can do the builds and where the resulting bits can be used.

NOTE: We expect a change here off these older Windows OS releases and to a 'less older' one, probably Windows 2008R2 X64.

With Linux, it was just a matter of picking a stable distribution that is a good representative for Linux in general.

It is understood that most developers will NOT be using these specific versions, and in fact creating these specific versions may be difficult due to the age of some of this software. It is expected that developers are more often using the more recent releases and distributions of these operating systems.

Compilation problems with newer or different C/C++ compilers is a common problem. Similarly, compilation problems related to changes to the /usr/include or system header files is also a common problem with older, newer, or unreleased OS versions. Please report these types of problems as bugs so that they can be dealt with accordingly.

Bootstrap JDK: JDK 8

Base OS and Architecture OS C/C++ Compiler Processors RAM Minimum DISK Needs
Linux X86 (32-bit) and X64 (64-bit) Oracle Enterprise Linux 6.4 gcc 4.9.2 2 or more 1 GB 6 GB
Solaris SPARCV9 (64-bit) Solaris 11 Update 1 Studio 12 Update 4 + patches 4 or more 4 GB 8 GB
Solaris X64 (64-bit) Solaris 11 Update 1 Studio 12 Update 4 + patches 4 or more 4 GB 8 GB
Windows X86 (32-bit) Windows Server 2012 R2 x64 Microsoft Visual Studio C++ 2013 Professional Edition 2 or more 2 GB 6 GB
Windows X64 (64-bit) Windows Server 2012 R2 x64 Microsoft Visual Studio C++ 2013 Professional Edition 2 or more 2 GB 6 GB
Mac OS X X64 (64-bit) Mac OS X 10.9 "Mavericks" Xcode 6.3 or newer 2 or more 4 GB 6 GB

Specific Developer Build Environments

We won't be listing all the possible environments, but we will try to provide what information we have available to us.

NOTE: The community can help out by updating this part of the document.

Fedora

After installing the latest Fedora you need to install several build dependencies. The simplest way to do it is to execute the following commands as user root:

  yum-builddep java-1.7.0-openjdk
  yum install gcc gcc-c++

In addition, it's necessary to set a few environment variables for the build:

  export LANG=C
  export PATH="/usr/lib/jvm/java-openjdk/bin:${PATH}"

CentOS 5.5

After installing CentOS 5.5 you need to make sure you have the following Development bundles installed:

Plus the following packages:

The freetype 2.3 packages don't seem to be available, but the freetype 2.3 sources can be downloaded, built, and installed easily enough from the freetype site. Build and install with something like:

  bash ./configure
  make
  sudo -u root make install

Mercurial packages could not be found easily, but a Google search should find ones, and they usually include Python if it's needed.

Debian 5.0 (Lenny)

After installing Debian 5 you need to install several build dependencies. The simplest way to install the build dependencies is to execute the following commands as user root:

  aptitude build-dep openjdk-7
  aptitude install openjdk-7-jdk libmotif-dev

In addition, it's necessary to set a few environment variables for the build:

  export LANG=C
  export PATH="/usr/lib/jvm/java-7-openjdk/bin:${PATH}"

Ubuntu 12.04

After installing Ubuntu 12.04 you need to install several build dependencies. The simplest way to do it is to execute the following commands:

  sudo aptitude build-dep openjdk-7
  sudo aptitude install openjdk-7-jdk

In addition, it's necessary to set a few environment variables for the build:

  export LANG=C
  export PATH="/usr/lib/jvm/java-7-openjdk/bin:${PATH}"

OpenSUSE 11.1

After installing OpenSUSE 11.1 you need to install several build dependencies. The simplest way to install the build dependencies is to execute the following commands:

  sudo zypper source-install -d java-1_7_0-openjdk
  sudo zypper install make

In addition, it is necessary to set a few environment variables for the build:

  export LANG=C
  export PATH="/usr/lib/jvm/java-1.7.0-openjdk/bin:$[PATH}"

Finally, you need to unset the JAVA_HOME environment variable:

  export -n JAVA_HOME`

Mandriva Linux One 2009 Spring

After installing Mandriva Linux One 2009 Spring you need to install several build dependencies. The simplest way to install the build dependencies is to execute the following commands as user root:

  urpmi java-1.7.0-openjdk-devel make gcc gcc-c++ freetype-devel zip unzip
    libcups2-devel libxrender1-devel libalsa2-devel libstc++-static-devel
    libxtst6-devel libxi-devel

In addition, it is necessary to set a few environment variables for the build:

  export LANG=C
  export PATH="/usr/lib/jvm/java-1.7.0-openjdk/bin:${PATH}"

OpenSolaris 2009.06

After installing OpenSolaris 2009.06 you need to install several build dependencies. The simplest way to install the build dependencies is to execute the following commands:

  pfexec pkg install SUNWgmake SUNWj7dev sunstudioexpress SUNWcups SUNWzip
    SUNWunzip SUNWxwhl SUNWxorg-headers SUNWaudh SUNWfreetype2

In addition, it is necessary to set a few environment variables for the build:

  export LANG=C
  export PATH="/opt/SunStudioExpress/bin:${PATH}"

End of the OpenJDK build README document.

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