src/source/initializing.md - platform/docs/source.android.com - Git at Google

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 # Initializing a Build Environment #

 The "Getting Started" section describes how to set up your local work environment, how to use Repo to get the Android files, and how to build the files on your machine.  To build the Android source files, you will need to use Linux or Mac OS. Building under Windows is not currently supported.

 *Note: The source download is approximately 6GB in size.
 You will need 25GB free to complete a single build, and
 up to 90GB (or more) for a full set of builds.*

 For an overview of the entire code-review and code-update process, see [Life of a Patch](life-of-a-patch.html).


 # Setting up a Linux build environment #

 The Android build is routinely tested in house on recent versions of
 Ubuntu LTS (10.04), but most distributions should have the required
 build tools available. Reports of successes or failures on other
 distributions are welcome.

 *Note: It is also possible to build Android in a virtual machine.
 If you are running Linux in a virtual machine, you will need at
 least 16GB of RAM/swap and 30GB or more of disk space in order to
 build the Android tree.*

 In general you will need:

  - Python 2.5 -- 2.7, which you can download from [python.org](http://www.python.org/download/).

  - GNU Make 3.81 -- 3.82, which you can download from [gnu.org](http://ftp.gnu.org/gnu/make/),

  - JDK 6 if you wish to build Gingerbread or newer; JDK 5 for Froyo or older.  You can download both from [java.sun.com](http://java.sun.com/javase/downloads/).

  - Git 1.7 or newer. You can find it at [git-scm.com](http://git-scm.com/download).

 Detailed instructions for Ubuntu 10.04+ follow.

 ## Installing the JDK ##

 The Sun JDK is no longer in Ubuntu's main package repository.  In order to download it, you need to add the appropriate repository and indicate to the system which JDK should be used.

 Java 6: for Gingerbread and newer

     $ sudo add-apt-repository "deb http://archive.canonical.com/ lucid partner"
     $ sudo apt-get update
     $ sudo apt-get install sun-java6-jdk

 Java 5: for Froyo and older

     $ sudo add-apt-repository "deb http://archive.ubuntu.com/ubuntu hardy main multiverse"
     $ sudo add-apt-repository "deb http://archive.ubuntu.com/ubuntu hardy-updates main multiverse"
     $ sudo apt-get update
     $ sudo apt-get install sun-java5-jdk

 *Note: The `lunch` command in the build step will ensure that the Sun JDK is
 used instead of any previously installed JDK.*

 ## Installing required packages (Ubuntu 10.04 -- 11.10) ##

 You will need a 64-bit version of Ubuntu.  Ubuntu 10.04 is recommended.
 Building using a newer version of Ubuntu is currently only experimentally
 supported and is not guaranteed to work on branches other than master.

     $ sudo apt-get install git-core gnupg flex bison gperf build-essential \
       zip curl zlib1g-dev libc6-dev lib32ncurses5-dev ia32-libs \
       x11proto-core-dev libx11-dev lib32readline5-dev lib32z-dev \
       libgl1-mesa-dev g++-multilib mingw32 tofrodos python-markdown \
       libxml2-utils xsltproc

 On Ubuntu 10.10:

     $ sudo ln -s /usr/lib32/mesa/libGL.so.1 /usr/lib32/mesa/libGL.so

 On Ubuntu 11.10:

     $ sudo apt-get install libx11-dev:i386

 ## Installing required packages (Ubuntu 12.04) ##

 Building on Ubuntu 12.04 is currently only experimentally supported and is not
 guaranteed to work on branches other than master.

     $ sudo apt-get install git-core gnupg flex bison gperf build-essential \
       zip curl libc6-dev libncurses5-dev:i386 x11proto-core-dev \
       libx11-dev:i386 libreadline6-dev:i386 libgl1-mesa-dev:i386 \
       g++-multilib mingw32 openjdk-6-jdk tofrodos python-markdown \
       libxml2-utils xsltproc zlib1g-dev:i386

 ## Configuring USB Access ##

 Under GNU/linux systems (and specifically under Ubuntu systems),
 regular users can't directly access USB devices by default. The
 system needs to be configured to allow such access.

 The recommended approach is to create a file
 `/etc/udev/rules.d/51-android.rules` (as the root user) and to copy
 the following lines in it. <username> must be replaced by the
 actual username of the user who is authorized to access the phones
 over USB.

     # adb protocol on passion (Nexus One)
     SUBSYSTEM=="usb", ATTR{idVendor}=="18d1", ATTR{idProduct}=="4e12", MODE="0600", OWNER="<username>"
     # fastboot protocol on passion (Nexus One)
     SUBSYSTEM=="usb", ATTR{idVendor}=="0bb4", ATTR{idProduct}=="0fff", MODE="0600", OWNER="<username>"
     # adb protocol on crespo/crespo4g (Nexus S)
     SUBSYSTEM=="usb", ATTR{idVendor}=="18d1", ATTR{idProduct}=="4e22", MODE="0600", OWNER="<username>"
     # fastboot protocol on crespo/crespo4g (Nexus S)
     SUBSYSTEM=="usb", ATTR{idVendor}=="18d1", ATTR{idProduct}=="4e20", MODE="0600", OWNER="<username>"
     # adb protocol on stingray/wingray (Xoom)
     SUBSYSTEM=="usb", ATTR{idVendor}=="22b8", ATTR{idProduct}=="70a9", MODE="0600", OWNER="<username>"
     # fastboot protocol on stingray/wingray (Xoom)
     SUBSYSTEM=="usb", ATTR{idVendor}=="18d1", ATTR{idProduct}=="708c", MODE="0600", OWNER="<username>"
     # adb protocol on maguro/toro (Galaxy Nexus)
     SUBSYSTEM=="usb", ATTR{idVendor}=="04e8", ATTR{idProduct}=="6860", MODE="0600", OWNER="<username>"
     # fastboot protocol on maguro/toro (Galaxy Nexus)
     SUBSYSTEM=="usb", ATTR{idVendor}=="18d1", ATTR{idProduct}=="4e30", MODE="0600", OWNER="<username>"
     # adb protocol on panda (PandaBoard)
     SUBSYSTEM=="usb", ATTR{idVendor}=="0451", ATTR{idProduct}=="d101", MODE="0600", OWNER="<username>"
     # fastboot protocol on panda (PandaBoard)
     SUBSYSTEM=="usb", ATTR{idVendor}=="0451", ATTR{idProduct}=="d022", MODE="0600", OWNER="<username>"
     # usbboot protocol on panda (PandaBoard)
     SUBSYSTEM=="usb", ATTR{idVendor}=="0451", ATTR{idProduct}=="d010", MODE="0600", OWNER="<username>"

 Those new rules take effect the next time a device is plugged in.
 It might therefore be necessary to unplug the device and plug it
 back into the computer.

 This is known to work on both Ubuntu Hardy Heron (8.04.x LTS) and
 Lucid Lynx (10.04.x LTS). Other versions of Ubuntu or other
 variants of GNU/linux might require different configurations.

 <a name="ccache"></a>
 ## Setting up ccache ##

 You can optionally tell the build to use the ccache compilation tool.
 Ccache acts as a compiler cache that can be used to speed-up rebuilds.
 This works very well if you do "make clean" often, or if you frequently
 switch between different build products.

 Put the following in your .bashrc or equivalent.

     export USE_CCACHE=1

 By default the cache will be stored in ~/.ccache.
 If your home directory is on NFS or some other non-local filesystem,
 you will want to specify the directory in your .bashrc as well.

     export CCACHE_DIR=<path-to-your-cache-directory>

 The suggested cache size is 50-100GB.
 You will need to run the following command once you have downloaded
 the source code.

     prebuilt/linux-x86/ccache/ccache -M 50G

 This setting is stored in the CCACHE_DIR and is persistent.


 # Setting up a Mac OS X build environment #

 To build the Android files in a Mac OS environment, you need an
 Intel/x86 machine running MacOS 10.6 (Snow Leopard).

 Android must be built on a case-sensitive file system because the sources contain files that differ only in case. We recommend that you build Android on a partition that has been formatted with the journaled file system HFS+.  HFS+ is required to successfully build Mac OS applications such as the Android Emulator for OS X.

 ## Creating a case sensitive disk image ##

 If you want to avoid partitioning/formatting your hard drive, you can use
 a case-sensitive disk image instead. To create the image, launch Disk
 Utility and select "New Image".  A size of 25GB is the minimum to
 complete the build, larger numbers are more future-proof. Using sparse images
 saves space while allowing to grow later as the need arises. Be sure to select
 "case sensitive, journaled" as the volume format.

 You can also create it from a shell with the following command:

     # hdiutil create -type SPARSE -fs 'Case-sensitive Journaled HFS+' -size 40g ~/android.dmg

 This will create a .dmg (or possibly a .dmg.sparsefile) file which, once mounted, acts as a drive with the required formatting for Android development. For a disk image named "android.dmg" stored in your home directory, you can add the following to your `~/.bash_profile` to mount the image when you execute "mountAndroid":

     # mount the android file image
     function mountAndroid { hdiutil attach ~/android.dmg -mountpoint /Volumes/android; }

 Once mounted, you'll do all your work in the "android" volume. You can eject it (unmount it) just like you would with an external drive.

 ## Installing required packages ##

 - Install XCode from [the Apple developer site](http://developer.apple.com/).
 We recommend version 3.1.4 or newer, i.e. gcc 4.2.
 Version 4.x could cause difficulties.
 If you are not already registered as an Apple developer, you will have to
 create an Apple ID in order to download.

 - Install MacPorts from [macports.org](http://www.macports.org/install.php).

     *Note: Make sure that `/opt/local/bin` appears in your path BEFORE `/usr/bin`.  If not, add*

         export PATH=/opt/local/bin:$PATH

     *to your `~/.bash_profile`.*

 - Get make, git, and GPG packages from MacPorts:

         $ POSIXLY_CORRECT=1 sudo port install gmake libsdl git-core gnupg

     If using Mac OS 10.4, also install bison:

         $ POSIXLY_CORRECT=1 sudo port install bison

 ## Reverting from make 3.82 ##

 For versions of Android before ICS, there is a bug in gmake 3.82 that prevents android from building.  You can install version 3.81 using MacPorts by taking the following steps:

 - Edit `/opt/local/etc/macports/sources.conf` and add a line that says

         file:///Users/Shared/dports

     above the rsync line.  Then create this directory:

         $ mkdir /Users/Shared/dports

 - In the new `dports` directory, run

         $ svn co --revision 50980 http://svn.macports.org/repository/macports/trunk/dports/devel/gmake/ devel/gmake/

 - Create a port index for your new local repository:

         $ portindex /Users/Shared/dports

 - Finally, install the old version of gmake with

         $ sudo port install gmake @3.81

 ## Setting a file descriptor limit ##

 On MacOS the default limit on the number of simultaneous file descriptors open is too low and a highly parallel build process may exceed this limit.

 To increase the cap, add the following lines to your `~/.bash_profile`:

     # set the number of open files to be 1024
     ulimit -S -n 1024

 # Next: Download the source #

 Your build environment is good to go!  Proceed to [downloading the source](downloading.html)....
	<!--
	Copyright 2010 The Android Open Source Project

	Licensed under the Apache License, Version 2.0 (the "License");
	you may not use this file except in compliance with the License.
	You may obtain a copy of the License at

	http://www.apache.org/licenses/LICENSE-2.0

	Unless required by applicable law or agreed to in writing, software
	distributed under the License is distributed on an "AS IS" BASIS,
	WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	See the License for the specific language governing permissions and
	limitations under the License.
	-->

	# Initializing a Build Environment #

	The "Getting Started" section describes how to set up your local work environment, how to use Repo to get the Android files, and how to build the files on your machine. To build the Android source files, you will need to use Linux or Mac OS. Building under Windows is not currently supported.

	*Note: The source download is approximately 6GB in size.
	You will need 25GB free to complete a single build, and
	up to 90GB (or more) for a full set of builds.*

	For an overview of the entire code-review and code-update process, see [Life of a Patch](life-of-a-patch.html).



	# Setting up a Linux build environment #

	The Android build is routinely tested in house on recent versions of
	Ubuntu LTS (10.04), but most distributions should have the required
	build tools available. Reports of successes or failures on other
	distributions are welcome.

	*Note: It is also possible to build Android in a virtual machine.
	If you are running Linux in a virtual machine, you will need at
	least 16GB of RAM/swap and 30GB or more of disk space in order to
	build the Android tree.*

	In general you will need:

	- Python 2.5 -- 2.7, which you can download from [python.org](http://www.python.org/download/).

	- GNU Make 3.81 -- 3.82, which you can download from [gnu.org](http://ftp.gnu.org/gnu/make/),

	- JDK 6 if you wish to build Gingerbread or newer; JDK 5 for Froyo or older. You can download both from [java.sun.com](http://java.sun.com/javase/downloads/).

	- Git 1.7 or newer. You can find it at [git-scm.com](http://git-scm.com/download).

	Detailed instructions for Ubuntu 10.04+ follow.

	## Installing the JDK ##

	The Sun JDK is no longer in Ubuntu's main package repository. In order to download it, you need to add the appropriate repository and indicate to the system which JDK should be used.

	Java 6: for Gingerbread and newer

	$ sudo add-apt-repository "deb http://archive.canonical.com/ lucid partner"
	$ sudo apt-get update
	$ sudo apt-get install sun-java6-jdk

	Java 5: for Froyo and older

	$ sudo add-apt-repository "deb http://archive.ubuntu.com/ubuntu hardy main multiverse"
	$ sudo add-apt-repository "deb http://archive.ubuntu.com/ubuntu hardy-updates main multiverse"
	$ sudo apt-get update
	$ sudo apt-get install sun-java5-jdk

	*Note: The `lunch` command in the build step will ensure that the Sun JDK is
	used instead of any previously installed JDK.*

	## Installing required packages (Ubuntu 10.04 -- 11.10) ##

	You will need a 64-bit version of Ubuntu. Ubuntu 10.04 is recommended.
	Building using a newer version of Ubuntu is currently only experimentally
	supported and is not guaranteed to work on branches other than master.

	$ sudo apt-get install git-core gnupg flex bison gperf build-essential \
	zip curl zlib1g-dev libc6-dev lib32ncurses5-dev ia32-libs \
	x11proto-core-dev libx11-dev lib32readline5-dev lib32z-dev \
	libgl1-mesa-dev g++-multilib mingw32 tofrodos python-markdown \
	libxml2-utils xsltproc

	On Ubuntu 10.10:

	$ sudo ln -s /usr/lib32/mesa/libGL.so.1 /usr/lib32/mesa/libGL.so

	On Ubuntu 11.10:

	$ sudo apt-get install libx11-dev:i386

	## Installing required packages (Ubuntu 12.04) ##

	Building on Ubuntu 12.04 is currently only experimentally supported and is not
	guaranteed to work on branches other than master.

	$ sudo apt-get install git-core gnupg flex bison gperf build-essential \
	zip curl libc6-dev libncurses5-dev:i386 x11proto-core-dev \
	libx11-dev:i386 libreadline6-dev:i386 libgl1-mesa-dev:i386 \
	g++-multilib mingw32 openjdk-6-jdk tofrodos python-markdown \
	libxml2-utils xsltproc zlib1g-dev:i386

	## Configuring USB Access ##

	Under GNU/linux systems (and specifically under Ubuntu systems),
	regular users can't directly access USB devices by default. The
	system needs to be configured to allow such access.

	The recommended approach is to create a file
	`/etc/udev/rules.d/51-android.rules` (as the root user) and to copy
	the following lines in it. <username> must be replaced by the
	actual username of the user who is authorized to access the phones
	over USB.

	# adb protocol on passion (Nexus One)
	SUBSYSTEM=="usb", ATTR{idVendor}=="18d1", ATTR{idProduct}=="4e12", MODE="0600", OWNER="<username>"
	# fastboot protocol on passion (Nexus One)
	SUBSYSTEM=="usb", ATTR{idVendor}=="0bb4", ATTR{idProduct}=="0fff", MODE="0600", OWNER="<username>"
	# adb protocol on crespo/crespo4g (Nexus S)
	SUBSYSTEM=="usb", ATTR{idVendor}=="18d1", ATTR{idProduct}=="4e22", MODE="0600", OWNER="<username>"
	# fastboot protocol on crespo/crespo4g (Nexus S)
	SUBSYSTEM=="usb", ATTR{idVendor}=="18d1", ATTR{idProduct}=="4e20", MODE="0600", OWNER="<username>"
	# adb protocol on stingray/wingray (Xoom)
	SUBSYSTEM=="usb", ATTR{idVendor}=="22b8", ATTR{idProduct}=="70a9", MODE="0600", OWNER="<username>"
	# fastboot protocol on stingray/wingray (Xoom)
	SUBSYSTEM=="usb", ATTR{idVendor}=="18d1", ATTR{idProduct}=="708c", MODE="0600", OWNER="<username>"
	# adb protocol on maguro/toro (Galaxy Nexus)
	SUBSYSTEM=="usb", ATTR{idVendor}=="04e8", ATTR{idProduct}=="6860", MODE="0600", OWNER="<username>"
	# fastboot protocol on maguro/toro (Galaxy Nexus)
	SUBSYSTEM=="usb", ATTR{idVendor}=="18d1", ATTR{idProduct}=="4e30", MODE="0600", OWNER="<username>"
	# adb protocol on panda (PandaBoard)
	SUBSYSTEM=="usb", ATTR{idVendor}=="0451", ATTR{idProduct}=="d101", MODE="0600", OWNER="<username>"
	# fastboot protocol on panda (PandaBoard)
	SUBSYSTEM=="usb", ATTR{idVendor}=="0451", ATTR{idProduct}=="d022", MODE="0600", OWNER="<username>"
	# usbboot protocol on panda (PandaBoard)
	SUBSYSTEM=="usb", ATTR{idVendor}=="0451", ATTR{idProduct}=="d010", MODE="0600", OWNER="<username>"

	Those new rules take effect the next time a device is plugged in.
	It might therefore be necessary to unplug the device and plug it
	back into the computer.

	This is known to work on both Ubuntu Hardy Heron (8.04.x LTS) and
	Lucid Lynx (10.04.x LTS). Other versions of Ubuntu or other
	variants of GNU/linux might require different configurations.

	<a name="ccache"></a>
	## Setting up ccache ##

	You can optionally tell the build to use the ccache compilation tool.
	Ccache acts as a compiler cache that can be used to speed-up rebuilds.
	This works very well if you do "make clean" often, or if you frequently
	switch between different build products.

	Put the following in your .bashrc or equivalent.

	export USE_CCACHE=1

	By default the cache will be stored in ~/.ccache.
	If your home directory is on NFS or some other non-local filesystem,
	you will want to specify the directory in your .bashrc as well.

	export CCACHE_DIR=<path-to-your-cache-directory>

	The suggested cache size is 50-100GB.
	You will need to run the following command once you have downloaded
	the source code.

	prebuilt/linux-x86/ccache/ccache -M 50G

	This setting is stored in the CCACHE_DIR and is persistent.


	# Setting up a Mac OS X build environment #

	To build the Android files in a Mac OS environment, you need an
	Intel/x86 machine running MacOS 10.6 (Snow Leopard).

	Android must be built on a case-sensitive file system because the sources contain files that differ only in case. We recommend that you build Android on a partition that has been formatted with the journaled file system HFS+. HFS+ is required to successfully build Mac OS applications such as the Android Emulator for OS X.

	## Creating a case sensitive disk image ##

	If you want to avoid partitioning/formatting your hard drive, you can use
	a case-sensitive disk image instead. To create the image, launch Disk
	Utility and select "New Image". A size of 25GB is the minimum to
	complete the build, larger numbers are more future-proof. Using sparse images
	saves space while allowing to grow later as the need arises. Be sure to select
	"case sensitive, journaled" as the volume format.

	You can also create it from a shell with the following command:

	# hdiutil create -type SPARSE -fs 'Case-sensitive Journaled HFS+' -size 40g ~/android.dmg

	This will create a .dmg (or possibly a .dmg.sparsefile) file which, once mounted, acts as a drive with the required formatting for Android development. For a disk image named "android.dmg" stored in your home directory, you can add the following to your `~/.bash_profile` to mount the image when you execute "mountAndroid":

	# mount the android file image
	function mountAndroid { hdiutil attach ~/android.dmg -mountpoint /Volumes/android; }

	Once mounted, you'll do all your work in the "android" volume. You can eject it (unmount it) just like you would with an external drive.

	## Installing required packages ##

	- Install XCode from [the Apple developer site](http://developer.apple.com/).
	We recommend version 3.1.4 or newer, i.e. gcc 4.2.
	Version 4.x could cause difficulties.
	If you are not already registered as an Apple developer, you will have to
	create an Apple ID in order to download.

	- Install MacPorts from [macports.org](http://www.macports.org/install.php).

	Note: Make sure that `/opt/local/bin` appears in your path BEFORE `/usr/bin`. If not, add

	export PATH=/opt/local/bin:$PATH

	to your `~/.bash_profile`.

	- Get make, git, and GPG packages from MacPorts:

	$ POSIXLY_CORRECT=1 sudo port install gmake libsdl git-core gnupg

	If using Mac OS 10.4, also install bison:

	$ POSIXLY_CORRECT=1 sudo port install bison

	## Reverting from make 3.82 ##

	For versions of Android before ICS, there is a bug in gmake 3.82 that prevents android from building. You can install version 3.81 using MacPorts by taking the following steps:

	- Edit `/opt/local/etc/macports/sources.conf` and add a line that says

	file:///Users/Shared/dports

	above the rsync line. Then create this directory:

	$ mkdir /Users/Shared/dports

	- In the new `dports` directory, run

	$ svn co --revision 50980 http://svn.macports.org/repository/macports/trunk/dports/devel/gmake/ devel/gmake/

	- Create a port index for your new local repository:

	$ portindex /Users/Shared/dports

	- Finally, install the old version of gmake with

	$ sudo port install gmake @3.81

	## Setting a file descriptor limit ##

	On MacOS the default limit on the number of simultaneous file descriptors open is too low and a highly parallel build process may exceed this limit.

	To increase the cap, add the following lines to your `~/.bash_profile`:

	# set the number of open files to be 1024
	ulimit -S -n 1024

	# Next: Download the source #

	Your build environment is good to go! Proceed to [downloading the source](downloading.html)....