来源: build/core/build-system.html
Android Build System
Android Build System
Status: Draft (as of May 18, 2006)
Contents
Objective
The primary goals of reworking the build system are (1) to make dependencies work more reliably, so that when files need to rebuilt, they are, and (2) to improve performance of the build system so that unnecessary modules are not rebuilt, and so doing a top-level build when little or nothing needs to be done for a build takes as little time as possible.
Principles and Use Cases and Policy
Given the above objective, these are the overall principles and use cases that we will support. This is not an exhaustive list.
Multiple Targets
It needs to be possible to build the Android platform for multiple targets. This means:
- The build system will support building tools for the host platform, both ones that are used in the build process itself, and developer tools like the simulator.
- The build system will need to be able to build tools on Linux (definitely Goobuntu and maybe Grhat), MacOS, and to some degree on Windows.
- The build system will need to be able to build the OS on Linux, and in the short-term, MacOS. Note that this is a conscious decision to stop building the OS on Windows. We are going to rely on the emulator there and not attempt to use the simulator. This is a requirement change now that the emulator story is looking brighter.
Non-Recursive Make
To achieve the objectives, the build system will be rewritten to use make non-recursively. For more background on this, read Recursive Make Considered Harmful. For those that don‘t want PDF, here is the Google translated version.
Rapid Compile-Test Cycles
When developing a component, for example a C++ shared library, it must be possible to easily rebuild just that component, and not have to wait more than a couple seconds for dependency checks, and not have to wait for unneeded components to be built.
Both Environment and Config File Based Settings
To set the target, and other options, some people on the team like to have a configuration file in a directory so they do not have an environment setup script to run, and others want an environment setup script to run so they can run builds in different terminals on the same tree, or switch back and forth in one terminal. We will support both.
Object File Directory / make clean
Object files and other intermediate files will be generated into a directory that is separate from the source tree. The goal is to have make clean be "rm -rf " in the tree root directory. The primary goals of this are to simplify searching the source tree, and to make "make clean" more reliable.
SDK
The SDK will be a tarball that will allow non-OS-developers to write apps. The apps will actually be built by first building the SDK, and then building the apps against that SDK. This will hopefully (1) make writing apps easier for us, because we won‘t have to rebuild the OS as much, and we can use the standard java-app development tools, and (2) allow us to dog-food the SDK, to help ensure its quality. Cedric has suggested (and I agree) that apps built from the SDK should be built with ant. Stay tuned for more details as we figure out exactly how this will work.
Dependecies
Dependencies should all be automatic. Unless there is a custom tool involved (e.g. the webkit has several), the dependencies for shared and static libraries, .c, .cpp, .h, .java, java libraries, etc., should all work without intervention in the Android.mk file.
Hiding command lines
The default of the build system will be to hide the command lines being executed for make steps. It will be possible to override this by specifying the showcommands pseudo-target, and possibly by setting an environment variable.
Wildcard source files
Wildcarding source file will be discouraged. It may be useful in some scenarios. The default $(wildcard *)
will not work due to the current directory being set to the root of the build tree.
Multiple targets in one directory
It will be possible to generate more than one target from a given subdirectory. For example, libutils generates a shared library for the target and a static library for the host.
Makefile fragments for modules
Android.mk is the standard name for the makefile fragments that control the building of a given module. Only the top directory should have a file named "Makefile".
Use shared libraries
Currently, the simulator is not built to use shared libraries. This should be fixed, and now is a good time to do it. This implies getting shared libraries to work on Mac OS.
Nice to Have
These things would be nice to have, and this is a good place to record them, however these are not promises.
Simultaneous Builds
The hope is to be able to do two builds for different combos in the same tree at the same time, but this is a stretch goal, not a requirement. Doing two builds in the same tree, not at the same time must work. (update: it‘s looking like we‘ll get the two builds at the same time working)
Deleting headers (or other dependecies)
Problems can arise if you delete a header file that is referenced in ".d" files. The easy way to deal with this is "make clean". There should be a better way to handle it. (from fadden)
One way of solving this is introducing a dependency on the directory. The problem is that this can create extra dependecies and slow down the build. It‘s a tradeoff.
Multiple builds
General way to perform builds across the set of known platforms. This would make it easy to perform multiple platform builds when testing a change, and allow a wide-scale "make clean". Right now the buildspec.mk or environment variables need to be updated before each build. (from fadden)
Aftermarket Locales and Carrier
We will eventually need to add support for creating locales and carrier customizations to the SDK, but that will not be addressed right now.
Usage
You‘ve read (or scrolled past) all of the motivations for this build system, and you want to know how to use it. This is the place.
Your first build
The Building document describes how do do builds.
build/envsetup.sh functions
If you source the file build/envsetup.sh into your bash environment, . build/envsetup.sh
you‘ll get a few helpful shell functions:
- printconfig - Prints the current configuration as set by the lunch and choosecombo commands.
-
m - Runs
make
from the top of the tree. This is useful because you can run make from within subdirectories. If you have theTOP
environment variable set, it uses that. If you don‘t, it looks up the tree from the current directory, trying to find the top of the tree. -
croot -
cd
to the top of the tree. - sgrep - grep for the regex you provide in all .c, .cpp, .h, .java, and .xml files below the current directory.
Build flavors/types
When building for a particular product, it‘s often useful to have minor variations on what is ultimately the final release build. These are the currently-defined "flavors" or "types" (we need to settle on a real name for these).
eng |
This is the default flavor. A plain "make " is the same as "make eng ". droid is an alias for eng .
|
user |
"make user "
This is the flavor intended to be the final release bits.
|
userdebug |
"make userdebug "
The same as
|
If you build one flavor and then want to build another, you should run "make installclean
" between the two makes to guarantee that you don‘t pick up files installed by the previous flavor. "make clean
" will also suffice, but it takes a lot longer.
More pseudotargets
Sometimes you want to just build one thing. The following pseudotargets are there for your convenience:
-
droid -
make droid
is the normal build. This target is here because the default target has to have a name. -
all -
make all
builds everythingmake droid
does, plus everything whoseLOCAL_MODULE_TAGS
do not include the "droid" tag. The build server runs this to make sure that everything that is in the tree and has an Android.mk builds. -
clean-$(LOCAL_MODULE) and clean-$(LOCAL_PACKAGE_NAME) - Let you selectively clean one target. For example, you can type
make clean-libutils
and it will delete libutils.so and all of the intermediate files, or you can typemake clean-Home
and it will clean just the Home app. -
clean -
make clean
deletes all of the output and intermediate files for this configuration. This is the same asrm -rf out/<configuration>/
-
clobber -
make clobber
deletes all of the output and intermediate files for all configurations. This is the same asrm -rf out/
. -
dataclean -
make dataclean
deletes contents of the data directory inside the current combo directory. This is especially useful on the simulator and emulator, where the persistent data remains present between builds. -
showcommands -
showcommands
is a modifier target which causes the build system to show the actual command lines for the build steps, instead of the brief descriptions. Most people don‘t like seeing the actual commands, because they‘re quite long and hard to read, but if you need to for debugging purposes, you can addshowcommands
to the list of targets you build. For examplemake showcommands
will build the default android configuration, andmake runtime showcommands
will build just the runtime, and targets that it depends on, while displaying the full command lines. Please note that there are a couple places where the commands aren‘t shown here. These are considered bugs, and should be fixed, but they‘re often hard to track down. Please let android-build-team know if you find any. -
LOCAL_MODULE - Anything you specify as a
LOCAL_MODULE
in an Android.mk is made into a pseudotarget. For example,make runtime
might be shorthand formake out/linux-x86-debug/system/bin/runtime
(which would work), andmake libkjs
might be shorthand formake out/linux-x86-debug/system/lib/libkjs.so
(which would also work). -
targets -
make targets
will print a list of all of the LOCAL_MODULE names you can make.
How to add another component to the build - Android.mk templates
You have a new library, a new app, or a new executable. For each of the common types of modules, there is a corresponding file in the templates directory. It will usually be enough to copy one of these, and fill in your own values. Some of the more esoteric values are not included in the templates, but are instead just documented here, as is the documentation on using custom tools to generate files.
Mostly, you can just look for the TODO comments in the templates and do what it says. Please remember to delete the TODO comments when you‘re done to keep the files clean. The templates have minimal documentation in them, because they‘re going to be copied, and when that gets stale, the copies just won‘t get updated. So read on...
Apps
Use the templates/apps
file.
This template is pretty self-explanitory. See the variables below for more details.
Java Libraries
Use the templates/java_library
file.
The interesting thing here is the value of LOCAL_MODULE, which becomes the name of the jar file. (Actually right now, we‘re not making jar files yet, just directories of .class files, but the directory is named according to what you put in LOCAL_MODULE). This name will be what goes in the LOCAL_JAVA_LIBRARIES variable in modules that depend on your java library.
C/C++ Executables
Use the templates/executable
file, or the templates/executable_host
file.
This template has a couple extra options that you usually don‘t need. Please delete the ones you don‘t need, and remove the TODO comments. It makes the rest of them easier to read, and you can always refer back to the templates if you need them again later.
By default, on the target these are built into /system/bin, and on the host, they‘re built into /host/bin. These can be overridden by setting LOCAL_MODULE_PATH
or LOCAL_MODULE_RELATIVE_PATH
. See Putting targets elsewhere for more.
Shared Libraries
Use the templates/shared_library
file, or the templates/shared_library_host
file.
Remember that on the target, we use shared libraries, and on the host, we use static libraries, since executable size isn‘t as big an issue, and it simplifies distribution in the SDK.
Static Libraries
Use the templates/static_library
file, or the templates/static_library_host
file.
Remember that on the target, we use shared libraries, and on the host, we use static libraries, since executable size isn‘t as big an issue, and it simplifies distribution in the SDK.
Using Custom Tools
If you have a tool that generates source files for you, it‘s possible to have the build system get the dependencies correct for it. Here are a couple of examples. $@
is the make built-in variable for "the current target." The red parts are the parts you‘ll need to change.
You need to put this after you have declared LOCAL_PATH
and LOCAL_MODULE
, because the $(local-generated-sources-dir)
and $(local-host-generated-sources-dir)
macros use these variables to determine where to put the files.
Example 1
Here, there is one generated file, called chartables.c, which doesn‘t depend on anything. And is built by the tool built to $(HOST_OUT_EXECUTABLES)/dftables. Note on the second to last line that a dependency is created on the tool.
intermediates:= $(local-generated-sources-dir) GEN := $(intermediates)/
chartables.c
$(GEN): PRIVATE_CUSTOM_TOOL =
$(HOST_OUT_EXECUTABLES)/dftables $@
$(GEN):
$(HOST_OUT_EXECUTABLES)/dftables
$(transform-generated-source) LOCAL_GENERATED_SOURCES += $(GEN)
Example 2
Here as a hypothetical example, we use use cat as if it were to transform a file. Pretend that it does something useful. Note how we use a target-specific variable called PRIVATE_INPUT_FILE to store the name of the input file.
intermediates:= $(local-generated-sources-dir) GEN := $(intermediates)/
file.c
$(GEN): PRIVATE_INPUT_FILE := $(LOCAL_PATH)/
input.file
$(GEN): PRIVATE_CUSTOM_TOOL =
cat $(PRIVATE_INPUT_FILE) > $@
$(GEN):
$(LOCAL_PATH)/file.c
$(transform-generated-source) LOCAL_GENERATED_SOURCES += $(GEN)
Example 3
If you have several files that are all similar in name, and use the same tool, you can combine them. (here the *.lut.h files are the generated ones, and the *.cpp files are the input files)
intermediates:= $(local-generated-sources-dir) GEN := $(addprefix $(intermediates)
/kjs/, \ array_object.lut.h \ bool_object.lut.h \
) $(GEN): PRIVATE_CUSTOM_TOOL =
perl libs/WebKitLib/WebKit/JavaScriptCore/kjs/create_hash_table $< -i > $@
$(GEN): $(intermediates)/
%.lut.h
: $(LOCAL_PATH)/
%.cpp
$(transform-generated-source) LOCAL_GENERATED_SOURCES += $(GEN)
Platform specific conditionals
Sometimes you need to set flags specifically for different platforms. Here is a list of which values the different build-system defined variables will be set to and some examples.
HOST_OS linux darwin |
HOST_ARCH x86 x86_64 |
HOST_BUILD_TYPE release debug |
TARGET_ARCH arm arm64 mips mips64 x86 x86_64 |
TARGET_BUILD_TYPE release debug |
There are also special variables to use instead of conditionals. Many of the normal variables (LOCAL_SRC_FILES, LOCAL_CFLAGS, etc) can be conditionally added to with _{arch} _{32|64}, and for the host, _{os}.
Some Examples
ifeq ($(TARGET_BUILD_TYPE),release) LOCAL_CFLAGS += -DNDEBUG=1 endif LOCAL_CFLAGS_arm += -DTARGET_IS_ARM LOCAL_CFLAGS_64 += -DBIG_POINTER # from libutils # Use the futex based mutex and condition variable # implementation from android-arm because it‘s shared mem safe LOCAL_SRC_FILES_linux += futex_synchro.c LOCAL_LDLIBS_linux += -lrt -ldl
Putting modules elsewhere
If you have modules that normally go somewhere, and you need to have them build somewhere else, read this.
If you have modules that need to go in a subdirectory of their normal location, for example HAL modules that need to go in /system/lib/hw or /vendor/lib/hw, set LOCAL_MODULE_RELATIVE_PATH in your Android.mk, for example:
LOCAL_MODULE_RELATIVE_PATH := hw
If you have modules that need to go in an entirely different location, for example the root filesystem instead of in /system, add these lines to your Android.mk:
LOCAL_MODULE_PATH := $(TARGET_ROOT_OUT_SBIN) LOCAL_UNSTRIPPED_PATH := $(TARGET_ROOT_OUT_SBIN_UNSTRIPPED)
For executables and libraries, you need to specify a LOCAL_UNSTRIPPED_PATH
location if you specified a LOCAL_MODULE_PATH
, because on target builds, we keep the unstripped executables so GDB can find the symbols. LOCAL_UNSTRIPPED_PATH
is not necessary if you only specified LOCAL_MODULE_RELATIVE_PATH
.
Look in core/envsetup.mk
for all of the variables defining places to build things.
FYI: If you‘re installing an executable to /sbin, you probably also want to set LOCAL_FORCE_STATIC_EXCUTABLE := true
in your Android.mk, which will force the linker to only accept static libraries.
Android.mk variables
These are the variables that you‘ll commonly see in Android.mk files, listed alphabetically.
But first, a note on variable naming:
-
LOCAL_ - These variables are set per-module. They are cleared by the
include $(CLEAR_VARS)
line, so you can rely on them being empty after including that file. Most of the variables you‘ll use in most modules are LOCAL_ variables. - PRIVATE_ - These variables are make-target-specific variables. That means they‘re only usable within the commands for that module. It also means that they‘re unlikely to change behind your back from modules that are included after yours. This link to the make documentation describes more about target-specific variables. Please note that there are a couple of these laying around the tree that aren‘t prefixed with PRIVATE_. It is safe, and they will be fixed as they are discovered. Sorry for the confusion.
- INTERNAL_ - These variables are critical to functioning of the build system, so you shouldn‘t create variables named like this, and you probably shouldn‘t be messing with these variables in your makefiles.
- HOST_ and TARGET_ - These contain the directories and definitions that are specific to either the host or the target builds. Do not set variables that start with HOST_ or TARGET_ in your makefiles.
- HOST_CROSS_ - These contain the directories and definitions that are specific to cross-building host binaries. The common case is building windows host tools on linux. Do not set variables that start with HOST_CROSS_ in your makefiles.
- BUILD_ and CLEAR_VARS - These contain the names of well-defined template makefiles to include. Some examples are CLEAR_VARS and BUILD_HOST_PACKAGE.
- Any other name is fair-game for you to use in your Android.mk. However, remember that this is a non-recursive build system, so it is possible that your variable will be changed by another Android.mk included later, and be different when the commands for your rule / module are executed.
LOCAL_ASSET_FILES
In Android.mk files that include $(BUILD_PACKAGE)
set this to the set of files you want built into your app. Usually:
LOCAL_ASSET_FILES += $(call find-subdir-assets)
This will probably change when we switch to ant for the apps‘ build system.
LOCAL_CC
If you want to use a different C compiler for this module, set LOCAL_CC to the path to the compiler. If LOCAL_CC is blank, the appropriate default compiler is used.
LOCAL_CXX
If you want to use a different C++ compiler for this module, set LOCAL_CXX to the path to the compiler. If LOCAL_CXX is blank, the appropriate default compiler is used.
LOCAL_CFLAGS
If you have additional flags to pass into the C or C++ compiler, add them here. For example:
LOCAL_CFLAGS += -DLIBUTILS_NATIVE=1
LOCAL_CPPFLAGS
If you have additional flags to pass into only the C++ compiler, add them here. For example:
LOCAL_CPPFLAGS += -ffriend-injection
LOCAL_CPPFLAGS
is guaranteed to be after LOCAL_CFLAGS
on the compile line, so you can use it to override flags listed in LOCAL_CFLAGS
.
LOCAL_CPP_EXTENSION
If your C++ files end in something other than ".cpp
", you can specify the custom extension here. For example:
LOCAL_CPP_EXTENSION := .cc
Note that all C++ files for a given module must have the same extension; it is not currently possible to mix different extensions.
LOCAL_NO_DEFAULT_COMPILER_FLAGS
Normally, the compile line for C and C++ files includes global include paths and global cflags. If LOCAL_NO_DEFAULT_COMPILER_FLAGS
is non-empty, none of the default includes or flags will be used when compiling C and C++ files in this module. LOCAL_C_INCLUDES
, LOCAL_CFLAGS
, and LOCAL_CPPFLAGS
will still be used in this case, as will any DEBUG_CFLAGS
that are defined for the module.
LOCAL_COPY_HEADERS
This will be going away.
The set of files to copy to the install include tree. You must also supply LOCAL_COPY_HEADERS_TO
.
This is going away because copying headers messes up the error messages, and may lead to people editing those headers instead of the correct ones. It also makes it easier to do bad layering in the system, which we want to avoid. We also aren‘t doing a C/C++ SDK, so there is no ultimate requirement to copy any headers.
LOCAL_COPY_HEADERS_TO
This will be going away.
The directory within "include" to copy the headers listed in LOCAL_COPY_HEADERS
to.
This is going away because copying headers messes up the error messages, and may lead to people editing those headers instead of the correct ones. It also makes it easier to do bad layering in the system, which we want to avoid. We also aren‘t doing a C/C++ SDK, so there is no ultimate requirement to copy any headers.
LOCAL_C_INCLUDES
Additional directories to instruct the C/C++ compilers to look for header files in. These paths are rooted at the top of the tree. Use LOCAL_PATH
if you have subdirectories of your own that you want in the include paths. For example:
LOCAL_C_INCLUDES += extlibs/zlib-1.2.3
LOCAL_C_INCLUDES += $(LOCAL_PATH)/src
You should not add subdirectories of include to
LOCAL_C_INCLUDES
, instead you should reference those files
in the #include
statement with their subdirectories. For
example:
#include <utils/KeyedVector.h>
not #include <KeyedVector.h>
There are some components that are doing this wrong, and should be cleaned up.
LOCAL_MODULE_TAGS
Set LOCAL_MODULE_TAGS
to any number of whitespace-separated
tags. If the tag list is empty or contains droid
, the module
will get installed as part of a make droid
. Otherwise, it will
only get installed by running make <your-module>
or with the make all
pseudotarget.
LOCAL_REQUIRED_MODULES
Set LOCAL_REQUIRED_MODULES
to any number of whitespace-separated
module names, like "libblah" or "Email". If this module is installed, all
of the modules that it requires will be installed as well. This can be
used to, e.g., ensure that necessary shared libraries or providers are
installed when a given app is installed.
LOCAL_FORCE_STATIC_EXECUTABLE
If your executable should be linked statically, set
LOCAL_FORCE_STATIC_EXECUTABLE:=true
. There is a very short
list of libraries that we have in static form (currently only libc). This is
really only used for executables in /sbin on the root filesystem.
LOCAL_GENERATED_SOURCES
Files that you add to LOCAL_GENERATED_SOURCES
will be
automatically generated and then linked in when your module is built.
See the Custom Tools template makefile for an
example.
LOCAL_JAVACFLAGS
If you have additional flags to pass into the javac compiler, add them here. For example:
LOCAL_JAVACFLAGS += -Xlint:deprecation
LOCAL_JAVA_LIBRARIES
When linking Java apps and libraries, LOCAL_JAVA_LIBRARIES
specifies which sets of java classes to include. Currently there are
two of these: core
and framework
.
In most cases, it will look like this:
LOCAL_JAVA_LIBRARIES := core framework
Note that setting LOCAL_JAVA_LIBRARIES
is not necessary
(and is not allowed) when building an APK with
"include $(BUILD_PACKAGE)
". The appropriate libraries
will be included automatically.
LOCAL_LDFLAGS
You can pass additional flags to the linker by setting
LOCAL_LDFLAGS
. Keep in mind that the order of parameters is
very important to ld, so test whatever you do on all platforms.
LOCAL_LDLIBS
LOCAL_LDLIBS
allows you to specify additional libraries
that are not part of the build for your executable or library. Specify
the libraries you want in -lxxx format; they‘re passed directly to the
link line. However, keep in mind that there will be no dependency generated
for these libraries. It‘s most useful in simulator builds where you want
to use a library preinstalled on the host. The linker (ld) is a particularly
fussy beast, so it‘s sometimes necessary to pass other flags here if you‘re
doing something sneaky. Some examples:
LOCAL_LDLIBS += -lcurses -lpthread
LOCAL_LDLIBS += -Wl,-z,origin
LOCAL_NO_MANIFEST
If your package doesn‘t have a manifest (AndroidManifest.xml), then
set LOCAL_NO_MANIFEST:=true
. The common resources package
does this.
LOCAL_PACKAGE_NAME
LOCAL_PACKAGE_NAME
is the name of an app. For example,
Dialer, Contacts, etc. This will probably change or go away when we switch
to an ant-based build system for the apps.
LOCAL_PATH
The directory your Android.mk file is in. You can set it by putting the following as the first line in your Android.mk:
LOCAL_PATH := $(my-dir)
The my-dir
macro uses the
MAKEFILE_LIST
variable, so you must call it before you include any other makefiles. Also,
consider that any subdirectories you inlcude might reset LOCAL_PATH, so do your
own stuff before you include them. This also means that if you try to write
several include
lines that reference LOCAL_PATH
,
it won‘t work, because those included makefiles might reset LOCAL_PATH.
LOCAL_POST_PROCESS_COMMAND
For host executables, you can specify a command to run on the module after it‘s been linked. You might have to go through some contortions to get variables right because of early or late variable evaluation:
module := $(HOST_OUT_EXECUTABLES)/$(LOCAL_MODULE)
LOCAL_POST_PROCESS_COMMAND := /Developer/Tools/Rez -d __DARWIN__ -t APPL\
-d __WXMAC__ -o $(module) Carbon.r
LOCAL_PREBUILT_EXECUTABLES
When including $(BUILD_MULTI_PREBUILT) or $(BUILD_HOST_PREBUILT), set these to executables that you want copied. They‘re located automatically into the right bin directory.
LOCAL_PREBUILT_LIBS
When including $(BUILD_MULTI_PREBUILT) or $(BUILD_HOST_PREBUILT), set these to libraries that you want copied. They‘re located automatically into the right lib directory.
LOCAL_SHARED_LIBRARIES
These are the libraries you directly link against. You don‘t need to pass transitively included libraries. Specify the name without the suffix:
LOCAL_SHARED_LIBRARIES := \
libutils \
libui \
libaudio \
libexpat \
libsgl
LOCAL_SRC_FILES
The build system looks at LOCAL_SRC_FILES
to know what source
files to compile -- .cpp .c .y .l .java. For lex and yacc files, it knows
how to correctly do the intermediate .h and .c/.cpp files automatically. If
the files are in a subdirectory of the one containing the Android.mk, prefix
them with the directory name:
LOCAL_SRC_FILES := \
file1.cpp \
dir/file2.cpp
LOCAL_STATIC_LIBRARIES
These are the static libraries that you want to include in your module. Mostly, we use shared libraries, but there are a couple of places, like executables in sbin and host executables where we use static libraries instead.
LOCAL_STATIC_LIBRARIES := \
libutils \
libtinyxml
LOCAL_MODULE
LOCAL_MODULE
is the name of what‘s supposed to be generated
from your Android.mk. For exmample, for libkjs, the LOCAL_MODULE
is "libkjs" (the build system adds the appropriate suffix -- .so .dylib .dll).
For app modules, use LOCAL_PACKAGE_NAME
instead of
LOCAL_MODULE
. We‘re planning on switching to ant for the apps,
so this might become moot.
LOCAL_MODULE_PATH
Instructs the build system to put the module somewhere other than what‘s
normal for its type. If you override this, make sure you also set
LOCAL_UNSTRIPPED_PATH
if it‘s an executable or a shared library
so the unstripped binary has somewhere to go. An error will occur if you forget
to.
See Putting modules elsewhere for more.
LOCAL_MODULE_RELATIVE_PATH
Instructs the build system to put the module in a subdirectory under the
directory that is normal for its type. If you set this you do not need to
set LOCAL_UNSTRIPPED_PATH
, the unstripped binaries will also use
the relative path.
See Putting modules elsewhere for more.
LOCAL_MODULE_HOST_OS
This specifies which OSes are supported by this host module. It is not used
for target builds. The accepted values here are combinations of
linux
, darwin
, and windows
. By default,
linux and darwin(MacOS) are considered to be supported. If a module should
build under windows, you must specify windows, and any others to be supported.
Some examples:
LOCAL_MODULE_HOST_OS := linux
LOCAL_MODULE_HOST_OS := darwin linux windows
LOCAL_UNSTRIPPED_PATH
Instructs the build system to put the unstripped version of the module
somewhere other than what‘s normal for its type. Usually, you override this
because you overrode LOCAL_MODULE_PATH
for an executable or a
shared library. If you overrode LOCAL_MODULE_PATH
, but not
LOCAL_UNSTRIPPED_PATH
, an error will occur.
See Putting modules elsewhere for more.
LOCAL_WHOLE_STATIC_LIBRARIES
These are the static libraries that you want to include in your module without allowing the linker to remove dead code from them. This is mostly useful if you want to add a static library to a shared library and have the static library‘s content exposed from the shared library.
LOCAL_WHOLE_STATIC_LIBRARIES := \
libsqlite3_android
LOCAL_YACCFLAGS
Any flags to pass to invocations of yacc for your module. A known limitation here is that the flags will be the same for all invocations of YACC for your module. This can be fixed. If you ever need it to be, just ask.
LOCAL_YACCFLAGS := -p kjsyy
Implementation Details
You should never have to touch anything in the config directory unless you‘re adding a new platform, new tools, or adding new features to the build system. In general, please consult with the build system owner(s) (android-build-team) before you go mucking around in here. That said, here are some notes on what‘s going on under the hood.
Environment Setup / buildspec.mk Versioning
In order to make easier for people when the build system changes, when it is necessary to make changes to buildspec.mk or to rerun the environment setup scripts, they contain a version number in the variable BUILD_ENV_SEQUENCE_NUMBER. If this variable does not match what the build system expects, it fails printing an error message explaining what happened. If you make a change that requires an update, you need to update two places so this message will be printed.
- In core/envsetup.mk, increment the CORRECT_BUILD_ENV_SEQUENCE_NUMBER definition.
- In buildspec.mk.default, update the BUILD_ENV_SEQUENCE_DUMBER definition to match the one in core/envsetup.mk
The scripts automatically get the value from the build system, so they will trigger the warning as well.
Additional makefile variables
You probably shouldn‘t use these variables. Please consult android-build-team before using them. These are mostly there for workarounds for other issues, or things that aren‘t completely done right.
LOCAL_ADDITIONAL_DEPENDENCIES
If your module needs to depend on anything else that
isn‘t actually built in to it, you can add those make targets to
LOCAL_ADDITIONAL_DEPENDENCIES
. Usually this is a workaround
for some other dependency that isn‘t created automatically.
LOCAL_BUILT_MODULE
This should not be used, since multiple binaries are now created from a single module defintiion.
When a module is built, the module is created in an intermediate directory then copied to its final location. LOCAL_BUILT_MODULE is the full path to the intermediate file. See LOCAL_INSTALLED_MODULE for the path to the final installed location of the module.
LOCAL_IS_HOST_MODULE
Set by the host_xxx.mk includes to tell base_rules.mk and the other includes that we‘re building for the host.
LOCAL_INSTALLED_MODULE
This should not be used, since multiple binaries are now created from a single module defintiion.
The fully qualified path name of the final location of the module. See LOCAL_BUILT_MODULE for the location of the intermediate file that the make rules should actually be constructing.
LOCAL_MODULE_CLASS
Which kind of module this is. This variable is used to construct other variable names used to locate the modules. See base_rules.mk and envsetup.mk.
LOCAL_MODULE_SUFFIX
The suffix that will be appended to LOCAL_MODULE
to form
LOCAL_MODULE_NAME
. For example, .so, .a, .dylib.
LOCAL_STRIP_MODULE
If set to true (the default), the binary will be stripped and a debug link will be set up so that GDB will still work. If set to no_debuglink, the binary will be stripped, but no debug link will be added. If set to keep_symbols, it will strip the debug information, but keep the symbol table. Any other value will prevent stripping.
LOCAL_SYSTEM_SHARED_LIBRARIES
Used while building the base libraries: libc, libm, libdl. Usually it should be set to "none," as it is in $(CLEAR_VARS). When building these libraries, it‘s set to the ones they link against. For example, libc, libstdc++ and libdl don‘t link against anything, and libm links against libc. Normally, when the value is none, these libraries are automatically linked in to executables and libraries, so you don‘t need to specify them manually.