分享一下我老师大神的人工智能教程!零基础,通俗易懂!http://blog.csdn.net/jiangjunshow
也欢迎大家转载本篇文章。分享知识,造福人民,实现我们中华民族伟大复兴!
Android源代码在编译之前,要先对编译环境进行初始化,其中最主要就是指定编译的类型和目标设备的型号。Android的编译类型主要有eng、userdebug和user三种,而支持的目标设备型号则是不确定的,它们由当前的源码配置情况所决定。为了确定源码支持的所有目标设备型号,Android编译系统在初始化的过程中,需要在特定的目录中加载特定的配置文件。接下来本文就对上述的初始化过程进行详细分析。
老罗的新浪微博:http://weibo.com/shengyangluo,欢迎关注!
《Android系统源代码情景分析》一书正在进击的程序员网(http://0xcc0xcd.com)中连载,点击进入!
对Android编译环境进行初始化很简单,分为两步。第一步是打开一个终端,并且将build/envsetup.sh加载到该终端中:
$ . ./build/envsetup.sh including device/asus/grouper/vendorsetup.shincluding device/asus/tilapia/vendorsetup.shincluding device/generic/armv7-a-neon/vendorsetup.shincluding device/generic/armv7-a/vendorsetup.shincluding device/generic/mips/vendorsetup.shincluding device/generic/x86/vendorsetup.shincluding device/lge/mako/vendorsetup.shincluding device/samsung/maguro/vendorsetup.shincluding device/samsung/manta/vendorsetup.shincluding device/samsung/toroplus/vendorsetup.shincluding device/samsung/toro/vendorsetup.shincluding device/ti/panda/vendorsetup.shincluding sdk/bash_completion/adb.bash第二步是执行命令lunch,如下所示:
$ lunchYou're building on LinuxLunch menu... pick a combo: 1. full-eng 2. full_x86-eng 3. vbox_x86-eng 4. full_mips-eng 5. full_grouper-userdebug 6. full_tilapia-userdebug 7. mini_armv7a_neon-userdebug 8. mini_armv7a-userdebug 9. mini_mips-userdebug 10. mini_x86-userdebug 11. full_mako-userdebug 12. full_maguro-userdebug 13. full_manta-userdebug 14. full_toroplus-userdebug 15. full_toro-userdebug 16. full_panda-userdebugWhich would you like? [full-eng] 当我们选定了一个Lunch菜单项序号(1-16)之后,按回车键,就可以完成Android编译环境的初始化过程。例如,我们选择1,可以看到以下输出:
Which would you like? [full-eng] 1============================================PLATFORM_VERSION_CODENAME=RELPLATFORM_VERSION=4.2TARGET_PRODUCT=fullTARGET_BUILD_VARIANT=engTARGET_BUILD_TYPE=releaseTARGET_BUILD_APPS=TARGET_ARCH=armTARGET_ARCH_VARIANT=armv7-aHOST_ARCH=x86HOST_OS=linuxHOST_OS_EXTRA=Linux-3.8.0-31-generic-x86_64-with-Ubuntu-13.04-raringHOST_BUILD_TYPE=releaseBUILD_ID=JOP40COUT_DIR=out============================================通过图1我们就可以直观地看到Android编译环境初始化完成后,我们所获得的东西:
图1 Android编译环境初始化完成之后
总体来说,Android编译环境初始化完成之后,获得了以下三样东西:
1. 将vendor和device目录下的vendorsetup.sh文件加载到了当前终端;
2. 新增了lunch、m、mm和mmm等命令;
3. 通过执行lunch命令设置好了TARGET_PRODUCT、TARGET_BUILD_VARIANT、TARGET_BUILD_TYPE和TARGET_BUILD_APPS等环境变量。
接下来我们就主要分析build/envsetup.sh文件的加载过程以及lunch命令的执行过程。
一. 文件build/envsetup.sh的加载过程
文件build/envsetup.sh是一个bash shell脚本,从它里面定义的函数hmm可以知道,它提供了lunch、m、mm和mmm等命令供我们初始化编译环境或者编译Android源码。
函数hmm的实现如下所示:
function hmm() {cat <<EOFInvoke ". build/envsetup.sh" from your shell to add the following functions to your environment:- lunch: lunch <product_name>-<build_variant>- tapas: tapas [<App1> <App2> ...] [arm|x86|mips] [eng|userdebug|user]- croot: Changes directory to the top of the tree.- m: Makes from the top of the tree.- mm: Builds all of the modules in the current directory.- mmm: Builds all of the modules in the supplied directories.- cgrep: Greps on all local C/C++ files.- jgrep: Greps on all local Java files.- resgrep: Greps on all local res/*.xml files.- godir: Go to the directory containing a file.Look at the source to view more functions. The complete list is:EOF T=$(gettop) local A A="" for i in `cat $T/build/envsetup.sh | sed -n "/^function /s/function \([a-z_]*\).*/\1/p" | sort`; do A="$A $i" done echo $A}函数hmm主要完成三个工作:
1. 调用另外一个函数gettop获得Android源码的根目录T。
2. 通过cat命令显示一个Here Document,说明$T/build/envsetup.sh文件加载到当前终端后所提供的主要命令。
3. 通过sed命令解析$T/build/envsetup.sh文件,并且获得在里面定义的所有函数的名称,这些函数名称就是$T/build/envsetup.sh文件加载到当前终端后提供的所有命令。
注意,sed命令是一个强大的文本分析工具,它以行为单位为执行文本替换、删除、新增和选取等操作。函数hmm通过执行以下的sed命令来获得在$T/build/envsetup.sh文件定义的函数的名称:
sed -n "/^function /s/function \([a-z_]*\).*/\1/p"文件build/envsetup.sh除了定义一堆函数之外,还有一个重要的代码段,如下所示:
# Execute the contents of any vendorsetup.sh files we can find.for f in `/bin/ls vendor/*/vendorsetup.sh vendor/*/*/vendorsetup.sh device/*/*/vendorsetup.sh 2> /dev/null`do echo "including $f" . $fdoneunset f这个for循环遍历vendor目录下的一级子目录和二级子目录以及device目录下的二级子目录中的vendorsetup.sh文件,并且通过source命令(.)将它们加载当前终端来。vendor和device相应子目录下的vendorsetup.sh文件的实现很简单,它们主要就是添加相应的设备型号及其编译类型支持到Lunch菜单中去。
例如,device/samsung/maguro目录下的vendorsetup.sh文件的实现如下所示:
add_lunch_combo full_maguro-userdebug函数add_lunch_combo定义在build/envsetup.sh文件中,它的实现如下所示:
function add_lunch_combo(){ local new_combo=$1 local c for c in ${LUNCH_MENU_CHOICES[@]} ; do if [ "$new_combo" = "$c" ] ; then return fi done LUNCH_MENU_CHOICES=(${LUNCH_MENU_CHOICES[@]} $new_combo)}数组LUNCH_MENU_CHOICES是定义在文件build/envsetup.sh的一个全局变量,当文件build/envsetup.sh被加载的时候,这个数组会被初始化为化full-eng、full_x86-eng、vbox_x86-eng和full_mips-eng,如下所示:
# add the default one hereadd_lunch_combo full-engadd_lunch_combo full_x86-engadd_lunch_combo vbox_x86-engadd_lunch_combo full_mips-eng二. lunch命令的执行过程
lunch命令实际上是定义在文件build/envsetup.sh的一个函数,它的实现如下所示:
function lunch(){ local answer if [ "$1" ] ; then answer=$1 else print_lunch_menu echo -n "Which would you like? [full-eng] " read answer fi local selection= if [ -z "$answer" ] then selection=full-eng elif (echo -n $answer | grep -q -e "^[0-9][0-9]*$") then if [ $answer -le ${#LUNCH_MENU_CHOICES[@]} ] then selection=${LUNCH_MENU_CHOICES[$(($answer-1))]} fi elif (echo -n $answer | grep -q -e "^[^\-][^\-]*-[^\-][^\-]*$") then selection=$answer fi if [ -z "$selection" ] then echo echo "Invalid lunch combo: $answer" return 1 fi export TARGET_BUILD_APPS= local product=$(echo -n $selection | sed -e "s/-.*$//") check_product $product if [ $? -ne 0 ] then echo echo "** Don't have a product spec for: '$product'" echo "** Do you have the right repo manifest?" product= fi local variant=$(echo -n $selection | sed -e "s/^[^\-]*-//") check_variant $variant if [ $? -ne 0 ] then echo echo "** Invalid variant: '$variant'" echo "** Must be one of ${VARIANT_CHOICES[@]}" variant= fi if [ -z "$product" -o -z "$variant" ] then echo return 1 fi export TARGET_PRODUCT=$product export TARGET_BUILD_VARIANT=$variant export TARGET_BUILD_TYPE=release echo set_stuff_for_environment printconfig}函数lunch的执行逻辑如下所示:
1. 检查是否带有参数,即位置参数$1是否等于空。如果不等于空的话,就表明带有参数,并且该参数是用来指定要编译的设备型号及其编译类型的。如果等于空的话,那么就调用另外一个函数print_lunch_menu来显示Lunch菜单项,并且通过调用read函数来等待用户输入。无论通过何种方式,最终变量answer的值就保存了用户所指定的备型号及其编译类型。
2. 对变量answer的值的合法性进行检查。如果等于空的话,就将它设置为默认值“full-eng”。如果不等于空的话,就分为三种情况考虑。第一种情况是值为数字,那么就需要确保该数字的大小不能超过Lunch菜单项的个数。在这种情况下,会将输入的数字索引到数组LUNCH_MENU_CHOICES中去,以便获得一个用来表示设备型号及其编译类型的文本。第二种情况是非数字文本,那么就需要确保该文本符合<product>-<variant>的形式,其中<product>表示设备型号,而<variant>表示编译类型 。第三种情况是除了前面两种情况之外的所有情况,这是非法的。经过合法性检查后,变量selection代表了用户所指定的备型号及其编译类型,如果它的值是非法的,即它的值等于空,那么函数lunch就不往下执行了。
3. 接下来是解析变量selection的值,也就是通过sed命令将它的<product>和<variant>值提取出来,并且分别保存在变量product和variant中。提取出来的product和variant值有可能是不合法的,因此需要进一步通过调用函数check_product和check_variant来检查。一旦检查失败,也就是函数check_product和check_variant的返回值$?等于非0,那么函数lunch就不往下执行了。
4. 通过以上合法性检查之后,就将变量product和variant的值保存在环境变量TARGET_PRODUCT和TARGET_BUILD_VARIANT中。此外,另外一个环境变量TARGET_BUILD_TYPE的值会被设置为"release",表示此次编译是一个release版本的编译。另外,前面还有一个环境变量TARGET_BUILD_APPS,它的值被函数lunch设置为空,用来表示此次编译是对整个系统进行编译。如果环境变量TARGET_BUILD_APPS的值不等于空,那么就表示此次编译是只对某些APP模块进行编译,而这些APP模块就是由环境变量TARGET_BUILD_APPS来指定的。
5. 调用函数set_stuff_for_environment来配置环境,例如设置Java SDK路径和交叉编译工具路径等。
6. 调用函数printfconfig来显示已经配置好的编译环境参数。
在上述执行过程中,函数check_product、check_variant和printconfig是比较关键的,因此接下来我们就继续分析它们的实现。
函数check_product定义在文件build/envsetup.sh中,它的实现如下所示:
# check to see if the supplied product is one we can buildfunction check_product(){ T=$(gettop) if [ ! "$T" ]; then echo "Couldn't locate the top of the tree. Try setting TOP." >&2 return fi CALLED_FROM_SETUP=true BUILD_SYSTEM=build/core \ TARGET_PRODUCT=$1 \ TARGET_BUILD_VARIANT= \ TARGET_BUILD_TYPE= \ TARGET_BUILD_APPS= \ get_build_var TARGET_DEVICE > /dev/null # hide successful answers, but allow the errors to show}接下来函数check_product设置几个环境变量,其中最重要的是前面三个CALLED_FROM_SETUP、BUILD_SYSTEM和TARGET_PRODUCT。环境变量CALLED_FROM_SETUP的值等于true表示接下来执行的make命令是用来初始化Android编译环境的。环境变量BUILD_SYSTEM用来指定Android编译系统的核心目录,它的值被设置为build/core。环境变量TARGET_PRODUCT用来表示要检查的产品名称(也就是我们前面说的设备型号),它的值被设置为$1,即函数check_product的调用参数。
最后函数check_product调用函数get_build_var来检查由环境变量TARGET_PRODUCT指定的产品名称是否合法,注意,它的调用参数为TARGET_DEVICE。
函数get_build_var定义在文件build/envsetup.sh中,它的实现如下所示:
# Get the exact value of a build variable.function get_build_var(){ T=$(gettop) if [ ! "$T" ]; then echo "Couldn't locate the top of the tree. Try setting TOP." >&2 return fi CALLED_FROM_SETUP=true BUILD_SYSTEM=build/core \ make --no-print-directory -C "$T" -f build/core/config.mk dumpvar-$1}文件build/core/config.mk的内容比较多,这里我们只关注与产品名称合法性检查相关的逻辑,这些逻辑也基本上涵盖了Android编译系统初始化的逻辑,如下所示:
......# ---------------------------------------------------------------# Define most of the global variables. These are the ones that# are specific to the user's build configuration.include $(BUILD_SYSTEM)/envsetup.mk# Boards may be defined under $(SRC_TARGET_DIR)/board/$(TARGET_DEVICE)# or under vendor/*/$(TARGET_DEVICE). Search in both places, but# make sure only one exists.# Real boards should always be associated with an OEM vendor.board_config_mk := \ $(strip $(wildcard \ $(SRC_TARGET_DIR)/board/$(TARGET_DEVICE)/BoardConfig.mk \ device/*/$(TARGET_DEVICE)/BoardConfig.mk \ vendor/*/$(TARGET_DEVICE)/BoardConfig.mk \ ))ifeq ($(board_config_mk),) $(error No config file found for TARGET_DEVICE $(TARGET_DEVICE))endififneq ($(words $(board_config_mk)),1) $(error Multiple board config files for TARGET_DEVICE $(TARGET_DEVICE): $(board_config_mk))endifinclude $(board_config_mk)......include $(BUILD_SYSTEM)/dumpvar.mk接下来我们就通过进入到build/core/envsetup.mk文件来分析变量TARGET_DEVICE的值是如何确定的:
# Read the product specs so we an get TARGET_DEVICE and other# variables that we need in order to locate the output files.include $(BUILD_SYSTEM)/product_config.mk文件build/core/product_config.mk的内容很多,这里我们只关注变量TARGET_DEVICE设置相关的逻辑,如下所示:
......ifneq ($(strip $(TARGET_BUILD_APPS)),)# An unbundled app build needs only the core product makefiles.all_product_configs := $(call get-product-makefiles,\ $(SRC_TARGET_DIR)/product/AndroidProducts.mk)else# Read in all of the product definitions specified by the AndroidProducts.mk# files in the tree.all_product_configs := $(get-all-product-makefiles)endif# all_product_configs consists items like:# <product_name>:<path_to_the_product_makefile># or just <path_to_the_product_makefile> in case the product name is the# same as the base filename of the product config makefile.current_product_makefile :=all_product_makefiles :=$(foreach f, $(all_product_configs),\ $(eval _cpm_words := $(subst :,$(space),$(f)))\ $(eval _cpm_word1 := $(word 1,$(_cpm_words)))\ $(eval _cpm_word2 := $(word 2,$(_cpm_words)))\ $(if $(_cpm_word2),\ $(eval all_product_makefiles += $(_cpm_word2))\ $(if $(filter $(TARGET_PRODUCT),$(_cpm_word1)),\ $(eval current_product_makefile += $(_cpm_word2)),),\ $(eval all_product_makefiles += $(f))\ $(if $(filter $(TARGET_PRODUCT),$(basename $(notdir $(f)))),\ $(eval current_product_makefile += $(f)),)))_cpm_words :=_cpm_word1 :=_cpm_word2 :=current_product_makefile := $(strip $(current_product_makefile))all_product_makefiles := $(strip $(all_product_makefiles))ifneq (,$(filter product-graph dump-products, $(MAKECMDGOALS)))# Import all product makefiles.$(call import-products, $(all_product_makefiles))else# Import just the current product.ifndef current_product_makefile$(error Cannot locate config makefile for product "$(TARGET_PRODUCT)")endififneq (1,$(words $(current_product_makefile)))$(error Product "$(TARGET_PRODUCT)" ambiguous: matches $(current_product_makefile))endif$(call import-products, $(current_product_makefile))endif # Import all or just the current product makefile......# Convert a short name like "sooner" into the path to the product# file defining that product.#INTERNAL_PRODUCT := $(call resolve-short-product-name, $(TARGET_PRODUCT))ifneq ($(current_product_makefile),$(INTERNAL_PRODUCT))$(error PRODUCT_NAME inconsistent in $(current_product_makefile) and $(INTERNAL_PRODUCT))endifcurrent_product_makefile :=all_product_makefiles :=all_product_configs :=# Find the device that this product maps to.TARGET_DEVICE := $(PRODUCTS.$(INTERNAL_PRODUCT).PRODUCT_DEVICE)......1. 检查环境变量TARGET_BUILD_APPS的值是否等于空。如果不等于空,那么就说明此次编译不是针对整个系统,因此只要将核心的产品相关的Makefile文件加载进来就行了,否则的话,就要将所有与产品相关的Makefile文件加载进来的。核心产品Makefile文件在$(SRC_TARGET_DIR)/product/AndroidProducts.mk文件中指定,也就是在build/target/product/AndroidProducts.mk文件,通过调用函数get-product-makefiles可以获得。所有与产品相关的Makefile文件可以通过另外一个函数get-all-product-makefiles获得。无论如何,最终获得的产品Makefie文件列表保存在变量all_product_configs中。
2. 遍历变量all_product_configs所描述的产品Makefile列表,并且在这些Makefile文件中,找到名称与环境变量TARGET_PRODUCT的值相同的文件,保存在另外一个变量current_product_makefile中,作为需要为当前指定的产品所加载的Makefile文件列表。在这个过程当中,上一步找到的所有的产品Makefile文件也会保存在变量all_product_makefiles中。注意,环境变量TARGET_PRODUCT的值是在我们执行lunch命令的时候设置并且传递进来的。
3. 如果指定的make目标等于product-graph或者dump-products,那么就将所有的产品相关的Makefile文件加载进来,否则的话,只加载与目标产品相关的Makefile文件。从前面的分析可以知道,此时的make目标为dumpvar-TARGET_DEVICE,因此接下来只会加载与目标产品,即$(TARGET_PRODUCT),相关的Makefile文件,这是通过调用另外一个函数import-products实现的。
4. 调用函数resolve-short-product-name解析环境变量TARGET_PRODUCT的值,将它变成一个Makefile文件路径。并且保存在变量INTERNAL_PRODUCT中。这里要求变量INTERNAL_PRODUCT和current_product_makefile的值相等,否则的话,就说明用户指定了一个非法的产品名称。
5. 找到一个名称为PRODUCTS.$(INTERNAL_PRODUCT).PRODUCT_DEVICE的变量,并且将它的值保存另外一个变量TARGET_DEVICE中。变量PRODUCTS.$(INTERNAL_PRODUCT).PRODUCT_DEVICE是在加载产品Makefile文件的过程中定义的,用来描述当前指定的产品的名称。
上述过程主要涉及到了get-all-product-makefiles、import-products和resolve-short-product-name三个关键函数,理解它们的执行过程对理解Android编译系统的初始化过程很有帮助,接下来我们分别分析它们的实现。
函数get-all-product-makefiles定义在文件build/core/product.mk中,如下所示:
## Returns the sorted concatenation of all PRODUCT_MAKEFILES# variables set in all AndroidProducts.mk files.# $(call ) isn't necessary.#define get-all-product-makefiles$(call get-product-makefiles,$(_find-android-products-files))endef函数_find-android-products-files也是定义在文件build/core/product.mk中,如下所示:
## Returns the list of all AndroidProducts.mk files.# $(call ) isn't necessary.#define _find-android-products-files$(shell test -d device && find device -maxdepth 6 -name AndroidProducts.mk) \ $(shell test -d vendor && find vendor -maxdepth 6 -name AndroidProducts.mk) \ $(SRC_TARGET_DIR)/product/AndroidProducts.mkendef函数get-product-makefiles也是定义在文件build/core/product.mk中,如下所示:
## Returns the sorted concatenation of PRODUCT_MAKEFILES# variables set in the given AndroidProducts.mk files.# $(1): the list of AndroidProducts.mk files.#define get-product-makefiles$(sort \ $(foreach f,$(1), \ $(eval PRODUCT_MAKEFILES :=) \ $(eval LOCAL_DIR := $(patsubst %/,%,$(dir $(f)))) \ $(eval include $(f)) \ $(PRODUCT_MAKEFILES) \ ) \ $(eval PRODUCT_MAKEFILES :=) \ $(eval LOCAL_DIR :=) \ )endef例如,在build/target/product/AndroidProducts.mk文件中,变量PRODUCT_MAKEFILES的值如下所示:
# Unbundled apps will be built with the most generic product config.ifneq ($(TARGET_BUILD_APPS),)PRODUCT_MAKEFILES := \ $(LOCAL_DIR)/full.mk \ $(LOCAL_DIR)/full_x86.mk \ $(LOCAL_DIR)/full_mips.mkelsePRODUCT_MAKEFILES := \ $(LOCAL_DIR)/core.mk \ $(LOCAL_DIR)/generic.mk \ $(LOCAL_DIR)/generic_x86.mk \ $(LOCAL_DIR)/generic_mips.mk \ $(LOCAL_DIR)/full.mk \ $(LOCAL_DIR)/full_x86.mk \ $(LOCAL_DIR)/full_mips.mk \ $(LOCAL_DIR)/vbox_x86.mk \ $(LOCAL_DIR)/sdk.mk \ $(LOCAL_DIR)/sdk_x86.mk \ $(LOCAL_DIR)/sdk_mips.mk \ $(LOCAL_DIR)/large_emu_hw.mkendif我们再来看函数import-products的实现,它定义在文件build/core/product.mk中,如下所示:
## $(1): product makefile list##TODO: check to make sure that products have all the necessary vars defineddefine import-products$(call import-nodes,PRODUCTS,$(1),$(_product_var_list))endef_product_var_list := \ PRODUCT_NAME \ PRODUCT_MODEL \ PRODUCT_LOCALES \ PRODUCT_AAPT_CONFIG \ PRODUCT_AAPT_PREF_CONFIG \ PRODUCT_PACKAGES \ PRODUCT_PACKAGES_DEBUG \ PRODUCT_PACKAGES_ENG \ PRODUCT_PACKAGES_TESTS \ PRODUCT_DEVICE \ PRODUCT_MANUFACTURER \ PRODUCT_BRAND \ PRODUCT_PROPERTY_OVERRIDES \ PRODUCT_DEFAULT_PROPERTY_OVERRIDES \ PRODUCT_CHARACTERISTICS \ PRODUCT_COPY_FILES \ PRODUCT_OTA_PUBLIC_KEYS \ PRODUCT_EXTRA_RECOVERY_KEYS \ PRODUCT_PACKAGE_OVERLAYS \ DEVICE_PACKAGE_OVERLAYS \ PRODUCT_TAGS \ PRODUCT_SDK_ADDON_NAME \ PRODUCT_SDK_ADDON_COPY_FILES \ PRODUCT_SDK_ADDON_COPY_MODULES \ PRODUCT_SDK_ADDON_DOC_MODULES \ PRODUCT_DEFAULT_WIFI_CHANNELS \ PRODUCT_DEFAULT_DEV_CERTIFICATE \ PRODUCT_RESTRICT_VENDOR_FILES \ PRODUCT_VENDOR_KERNEL_HEADERS \ PRODUCT_FACTORY_RAMDISK_MODULES \ PRODUCT_FACTORY_BUNDLE_MODULES函数import-nodes定义在文件build/core/node_fns.mk中,如下所示:
## $(1): output list variable name, like "PRODUCTS" or "DEVICES"# $(2): list of makefiles representing nodes to import# $(3): list of node variable names#define import-nodes$(if \ $(foreach _in,$(2), \ $(eval _node_import_context := _nic.$(1).[[$(_in)]]) \ $(if $(_include_stack),$(eval $(error ASSERTION FAILED: _include_stack \ should be empty here: $(_include_stack))),) \ $(eval _include_stack := ) \ $(call _import-nodes-inner,$(_node_import_context),$(_in),$(3)) \ $(call move-var-list,$(_node_import_context).$(_in),$(1).$(_in),$(3)) \ $(eval _node_import_context :=) \ $(eval $(1) := $($(1)) $(_in)) \ $(if $(_include_stack),$(eval $(error ASSERTION FAILED: _include_stack \ should be empty here: $(_include_stack))),) \ ) \,)endef1. 调用函数_import-nodes-inner将参数$2描述的每一个产品Makefile文件加载进来。
2. 调用函数move-var-list将定义在前面所加载的产品Makefile文件里面的由参数$3指定的变量的值分别拷贝到另外一组独立的变量中。
3. 将参数$2描述的每一个产品Makefile文件路径以空格分隔保存在参数$1所描述的变量中,也就是保存在变量PRODUCTS中。
上述第二件事情需要进一步解释一下。由于当前加载的每一个文件都会定义相同的变量,为了区分这些变量,我们需要在这些变量前面加一些前缀。例如,假设加载了build/target/product/full.mk这个产品Makefile文件,它里面定义了以下几个变量:
# OverridesPRODUCT_NAME := fullPRODUCT_DEVICE := genericPRODUCT_BRAND := AndroidPRODUCT_MODEL := Full Android on EmulatorPRODUCTS.build/target/product/full.mk.PRODUCT_NAME := fullPRODUCTS.build/target/product/full.mk.PRODUCT_DEVICE := genericPRODUCTS.build/target/product/full.mk.PRODUCT_BRAND := AndroidPRODUCTS.build/target/product/full.mk.PRODUCT_MODEL := Full Android on Emulator回到build/core/config.mk文件中,接下来我们再看BoardConfig.mk文件的加载过程。前面提到,当前要加载的BoardConfig.mk文件由变量TARGET_DEVICE来确定。例如,假设我们在运行lunch命令时,输入的文本为full-eng,那么build/target/product/full.mk就会被加载,并且我们得到TARGET_DEVICE的值就为generic,接下来加载的BoradConfig.mk文件就会在build/target/board/generic目录中找到。
BoardConfig.mk文件定义的信息可以参考build/target/board/generic/BoardConfig.mk文件的内容,如下所示:
# config.mk## Product-specific compile-time definitions.## The generic product target doesn't have any hardware-specific pieces.TARGET_NO_BOOTLOADER := trueTARGET_NO_KERNEL := trueTARGET_ARCH := arm# Note: we build the platform images for ARMv7-A _without_ NEON.## Technically, the emulator supports ARMv7-A _and_ NEON instructions, but# emulated NEON code paths typically ends up 2x slower than the normal C code# it is supposed to replace (unlike on real devices where it is 2x to 3x# faster).## What this means is that the platform image will not use NEON code paths# that are slower to emulate. On the other hand, it is possible to emulate# application code generated with the NDK that uses NEON in the emulator.#TARGET_ARCH_VARIANT := armv7-aTARGET_CPU_ABI := armeabi-v7aTARGET_CPU_ABI2 := armeabiARCH_ARM_HAVE_TLS_REGISTER := trueHAVE_HTC_AUDIO_DRIVER := trueBOARD_USES_GENERIC_AUDIO := true# no hardware cameraUSE_CAMERA_STUB := true# Enable dex-preoptimization to speed up the first boot sequence# of an SDK AVD. Note that this operation only works on Linux for nowifeq ($(HOST_OS),linux) ifeq ($(WITH_DEXPREOPT),) WITH_DEXPREOPT := true endifendif# Build OpenGLES emulation guest and host librariesBUILD_EMULATOR_OPENGL := true# Build and enable the OpenGL ES View renderer. When running on the emulator,# the GLES renderer disables itself if host GL acceleration isn't available.USE_OPENGL_RENDERER := true再回到build/core/config.mk文件中,它最后加载build/core/dumpvar.mk文件。加载build/core/dumpvar.mk文件是为了生成make目标,以便可以对这些目标进行操作。例如,在我们这个情景中,我们要执行的make目标是dumpvar-TARGET_DEVICE,因此在加载build/core/dumpvar.mk文件的过程中,就会生成dumpvar-TARGET_DEVICE目标。
文件build/core/dumpvar.mk的内容也比较多,这里我们只关注生成make目标相关的逻辑:
......# The "dumpvar" stuff lets you say something like## CALLED_FROM_SETUP=true \# make -f config/envsetup.make dumpvar-TARGET_OUT# or# CALLED_FROM_SETUP=true \# make -f config/envsetup.make dumpvar-abs-HOST_OUT_EXECUTABLES## The plain (non-abs) version just dumps the value of the named variable.# The "abs" version will treat the variable as a path, and dumps an# absolute path to it.#dumpvar_goals := \ $(strip $(patsubst dumpvar-%,%,$(filter dumpvar-%,$(MAKECMDGOALS))))ifdef dumpvar_goals ifneq ($(words $(dumpvar_goals)),1) $(error Only one "dumpvar-" goal allowed. Saw "$(MAKECMDGOALS)") endif # If the goal is of the form "dumpvar-abs-VARNAME", then # treat VARNAME as a path and return the absolute path to it. absolute_dumpvar := $(strip $(filter abs-%,$(dumpvar_goals))) ifdef absolute_dumpvar dumpvar_goals := $(patsubst abs-%,%,$(dumpvar_goals)) ifneq ($(filter /%,$($(dumpvar_goals))),) DUMPVAR_VALUE := $($(dumpvar_goals)) else DUMPVAR_VALUE := $(PWD)/$($(dumpvar_goals)) endif dumpvar_target := dumpvar-abs-$(dumpvar_goals) else DUMPVAR_VALUE := $($(dumpvar_goals)) dumpvar_target := dumpvar-$(dumpvar_goals) endif.PHONY: $(dumpvar_target)$(dumpvar_target): @echo $(DUMPVAR_VALUE)endif # dumpvar_goals...... 上述代码的逻辑很简单,例如,在我们这个情景中,指定的make目标为dumpvar-TARGET_DEVICE,那么就会得到变量DUMPVAR_VALUE的值为$(TARGET_DEVICE)。TARGET_DEVICE的值在前面已经被设置为“generic”,因此变量DUMPVAR_VALUE的值就等于“generic”。此外,变量dumpvar_target的被设置为“dumpvar-TARGET_DEVICE”。最后我们就可以得到以下的make规则:
.PHONY dumpvar-TARGET_DEVICEdumpvar-TARGET_DEVICE: @echo generic接下来我们还要继续分析在build/envsetup.sh文件中定义的函数check_variant的实现,如下所示:
VARIANT_CHOICES=(user userdebug eng)# check to see if the supplied variant is validfunction check_variant(){ for v in ${VARIANT_CHOICES[@]} do if [ "$v" = "$1" ] then return 0 fi done return 1}最后,我们再来分析在build/envsetup.sh文件中定义的函数printconfig的实现,如下所示:
function printconfig(){ T=$(gettop) if [ ! "$T" ]; then echo "Couldn't locate the top of the tree. Try setting TOP." >&2 return fi get_build_var report_config}我们跳过前面build/core/config.mk和build/core/envsetup.mk等文件对目标产品Makefile文件的加载,直接跳到build/core/dumpvar.mk文件来查看与report_config这个make目标相关的逻辑:
......dumpvar_goals := \ $(strip $(patsubst dumpvar-%,%,$(filter dumpvar-%,$(MAKECMDGOALS)))).....ifneq ($(dumpvar_goals),report_config)PRINT_BUILD_CONFIG:=endif......ifneq ($(PRINT_BUILD_CONFIG),)HOST_OS_EXTRA:=$(shell python -c "import platform; print(platform.platform())")$(info ============================================)$(info PLATFORM_VERSION_CODENAME=$(PLATFORM_VERSION_CODENAME))$(info PLATFORM_VERSION=$(PLATFORM_VERSION))$(info TARGET_PRODUCT=$(TARGET_PRODUCT))$(info TARGET_BUILD_VARIANT=$(TARGET_BUILD_VARIANT))$(info TARGET_BUILD_TYPE=$(TARGET_BUILD_TYPE))$(info TARGET_BUILD_APPS=$(TARGET_BUILD_APPS))$(info TARGET_ARCH=$(TARGET_ARCH))$(info TARGET_ARCH_VARIANT=$(TARGET_ARCH_VARIANT))$(info HOST_ARCH=$(HOST_ARCH))$(info HOST_OS=$(HOST_OS))$(info HOST_OS_EXTRA=$(HOST_OS_EXTRA))$(info HOST_BUILD_TYPE=$(HOST_BUILD_TYPE))$(info BUILD_ID=$(BUILD_ID))$(info OUT_DIR=$(OUT_DIR))$(info ============================================)endif至此,我们就分析完成Android编译系统环境的初始化过程了。从分析的过程可以知道,Android编译系统环境是由build/core/config.mk、build/core/envsetup.mk、build/core/product_config.mk、AndroidProducts.mk和BoardConfig.mk等文件来完成的。这些mk文件涉及到非常多的细节,而我们这里只提供了一个大体的骨架和脉络,希望能够起到抛砖引玉的作用。
有了Android编译系统环境的初始化过程知识之后,在接下来的一篇文章中,老罗将继续分析Android编译系统提供的m/mm/mmm编译命令,敬请关注!更多信息也可以关注老罗的新浪微博:http://weibo.com/shengyangluo
给我老师的人工智能教程打call!http://blog.csdn.net/jiangjunshow
