Android系统启动之Init流程(下)
下面开始
启动代码(main)
主要分为七部分:
第一部分
判断启动部分,如果是ueventd,调用ueventd_main主函数,如果是watchdogd,调用watchdogd_main主函数.
第二部分
add_environment导入环境变量,并根据环境变量判断是否是第一次启动.
第三部分
创建一些基本的目录,包括/dev、/porc、/sysfc等。同时把一些文件系统,如tmpfs、devpt、proc、sysfs等mount到项目的目录。
目录 | 功能 |
|---|---|
tmpfs | 一种基于内存的文件系统,mount后就可以使用。tmpfs文件系统下的文件都存放在内存中,访问速度快,但是关机后所有内容偶读会丢失,因此tmpfs文件系统比较合适存放一些临时性的文件。 |
devpts | 虚拟终端文件系统,它通常mount在目录dev/pts下 |
proc | 一种基于内存的虚拟文件系统,它可以看作是内核内部数据结构的接口,通过它可以获得系统的信息,同时能够在运行时修改特定的内核参数 |
sysfs | proc文件系统类似,它是Linux2.6内核引入的,作用是把系统的设备和总线按层次组织起来,使得它们可以在用户空间存取 |
然后使用InitKernelLogging开启log,使得init进程可以使用kernel的log系统来输出log.
为什么要使用kernel的log系统?
因为此时Android系统的log还没有启动,所以需要使用kernel的log系统.
第四部分
SELinex的知识参考android之SELinux小记
主要使用函数selinux_initialize启动SELinux.
另外:
close(open("/dev/.booting", O_WRONLY | O_CREAT | O_CLOEXEC, 0000));判断/dev/.booting文件是否可读写和创建.
在/dev目录下创建一个空文件".booting"表示初始化正在进行 is_booting()函数会依靠空文件".booting"来判断是否进程处于初始化中,初始化结束后,这个文件会被删除
第五部分
初始化系统属性存储区域:
property_init();property_init函数在system/core/init/property_service.cpp实现:
void property_init() {
if (__system_property_area_init()) {
LOG(ERROR) << "Failed to initialize property area";
exit(1);
}
}然后,设定内核处理命令行.
并设定相关系统属性export_kernel_boot_props:
static void export_kernel_boot_props() {
struct {
const char *src_prop;
const char *dst_prop;
const char *default_value;
} prop_map[] = {
{ "ro.boot.serialno", "ro.serialno", "", },
{ "ro.boot.mode", "ro.bootmode", "unknown", },
{ "ro.boot.baseband", "ro.baseband", "unknown", },
{ "ro.boot.bootloader", "ro.bootloader", "unknown", },
{ "ro.boot.hardware", "ro.hardware", "unknown", },
{ "ro.boot.revision", "ro.revision", "0", },
};
for (size_t i = 0; i < arraysize(prop_map); i++) {
std::string value = GetProperty(prop_map[i].src_prop, "");
property_set(prop_map[i].dst_prop, (!value.empty()) ? value : prop_map[i].defau lt_value);
}
}export_kernel_boot_props这个函数,它就是设置一些属性,设置ro属性根据之前的ro.boot这类的属性值,如果没有设置成unknown,像之前我们有ro.boot.hardware,那我们就可以设置root.hardware这样的属性。
第六部分
- 调用epoll_create1创建epoll句柄,如果创建失败,则退出。
- 调用signal_handler_init()函数,装载进程信号处理器。
- 调用property_load_boot_defaults()函数解析根目录的default.prop的属性,设置默认属性配置的相关工作。
- 调用start_prperty_service()函数,启动属性服务,并接受属性的socket的fd加入到epoll中,定义了处理函数。
- 解析rc文件(重要).参考:Android系统启动之init.rc文件解析过程
signal_handler_init函数主要是当子进程被kill之后,会在父进程接受一个信号。
处理这个信号的时候往sockpair一段写数据,而另一端的fd是加入epoll中
init是一个守护进程,为了防止init的子进程称为僵尸进程(zombie process),需要init在子进程结束时获取子进程的结束码,通过结束码将程序表中的子进程移除,防止称为僵尸进程的子进程占用程序表的空间(程序表的空间达到上线时,系统就不能再启动新的进城了,会引起严重的系统问题)。
第七部分
启动守护进程
源码如下
int main(int argc, char** argv) {
//---------------------第一部分------------------------------------
// 根据传入的参数,运行不同的主函数
//----------------------------------------------------------------------
//匹配启动程序名
if (!strcmp(basename(argv[0]), "ueventd")) {
return ueventd_main(argc, argv);
}
if (!strcmp(basename(argv[0]), "watchdogd")) {
return watchdogd_main(argc, argv);
}
if (REBOOT_BOOTLOADER_ON_PANIC) {
InstallRebootSignalHandlers();
}
//---------------------第二部分--------------------------------------
// 设定环境变量
//----------------------------------------------------------------------
//设定环境变量
add_environment("PATH", _PATH_DEFPATH);
bool is_first_stage = (getenv("INIT_SECOND_STAGE") == nullptr);
//判断是否是第一次
if (is_first_stage) {
boot_clock::time_point start_time = boot_clock::now();
// Clear the umask.
// 清楚权限掩码
umask(0);
//----------------------第三部分-------------------------------------
// 设定文件目录并挂载对应的设备
//----------------------------------------------------------------------
// Get the basic filesystem setup we need put together in the initramdisk
// on / and then we'll let the rc file figure out the rest.
// 创建文件系统和对应的权限,并挂载
mount("tmpfs", "/dev", "tmpfs", MS_NOSUID, "mode=0755");
mkdir("/dev/pts", 0755);
mkdir("/dev/socket", 0755);
mount("devpts", "/dev/pts", "devpts", 0, NULL);
#define MAKE_STR(x) __STRING(x)
mount("proc", "/proc", "proc", 0, "hidepid=2,gid=" MAKE_STR(AID_READPROC));
// Don't expose the raw commandline to unprivileged processes.
chmod("/proc/cmdline", 0440);
gid_t groups[] = { AID_READPROC };
setgroups(arraysize(groups), groups);
mount("sysfs", "/sys", "sysfs", 0, NULL);
mount("selinuxfs", "/sys/fs/selinux", "selinuxfs", 0, NULL);
mknod("/dev/kmsg", S_IFCHR | 0600, makedev(1, 11));
mknod("/dev/random", S_IFCHR | 0666, makedev(1, 8));
mknod("/dev/urandom", S_IFCHR | 0666, makedev(1, 9));
// Now that tmpfs is mounted on /dev and we have /dev/kmsg, we can actually
// talk to the outside world...
//初始化log
InitKernelLogging(argv);
LOG(INFO) << "init first stage started!";
if (!DoFirstStageMount()) {
LOG(ERROR) << "Failed to mount required partitions early ...";
panic();
}
SetInitAvbVersionInRecovery();
//-----------------------第四部分-------------------------------------
// 启动SELinux,根据SELinux的配置重新启动init
//----------------------------------------------------------------------
// Set up SELinux, loading the SELinux policy.
// 设置SELinux,加载SEPolicy
selinux_initialize(true);
// We're in the kernel domain, so re-exec init to transition to the init domain now
// that the SELinux policy has been loaded.
// 根据SELinux的要求重新设定init文件属性
if (restorecon("/init") == -1) {
PLOG(ERROR) << "restorecon failed";
security_failure();
}
setenv("INIT_SECOND_STAGE", "true", 1);
static constexpr uint32_t kNanosecondsPerMillisecond = 1e6;
uint64_t start_ms = start_time.time_since_epoch().count() / kNanosecondsPerMillisecond;
setenv("INIT_STARTED_AT", StringPrintf("%" PRIu64, start_ms).c_str(), 1);
//设定参数
char* path = argv[0];
char* args[] = { path, nullptr };
execv(path, args);
// execv() only returns if an error happened, in which case we
// panic and never fall through this conditional.
PLOG(ERROR) << "execv(\"" << path << "\") failed";
security_failure();
}
// At this point we're in the second stage of init.
InitKernelLogging(argv);
LOG(INFO) << "init second stage started!";
// Set up a session keyring that all processes will have access to. It
// will hold things like FBE encryption keys. No process should override
// its session keyring.
keyctl_get_keyring_ID(KEY_SPEC_SESSION_KEYRING, 1);
// Indicate that booting is in progress to background fw loaders, etc.
close(open("/dev/.booting", O_WRONLY | O_CREAT | O_CLOEXEC, 0000));
//-----------------------第五部分-------------------------------------
// 运行属性服务,根据属性值设定内核命令
//----------------------------------------------------------------------
//设定属性值
property_init();
// If arguments are passed both on the command line and in DT,
// properties set in DT always have priority over the command-line ones.
process_kernel_dt();
process_kernel_cmdline();
// Propagate the kernel variables to internal variables
// used by init as well as the current required properties.
export_kernel_boot_props();
// Make the time that init started available for bootstat to log.
property_set("ro.boottime.init", getenv("INIT_STARTED_AT"));
property_set("ro.boottime.init.selinux", getenv("INIT_SELINUX_TOOK"));
// Set libavb version for Framework-only OTA match in Treble build.
const char* avb_version = getenv("INIT_AVB_VERSION");
if (avb_version) property_set("ro.boot.avb_version", avb_version);
// Clean up our environment.
unsetenv("INIT_SECOND_STAGE");
unsetenv("INIT_STARTED_AT");
unsetenv("INIT_SELINUX_TOOK");
unsetenv("INIT_AVB_VERSION");
// Now set up SELinux for second stage.
selinux_initialize(false);
selinux_restore_context();
//-----------------------第六部分------------------------------------
// 启动服务,并解析rc文件,根据rc文件启动进程
//----------------------------------------------------------------------
epoll_fd = epoll_create1(EPOLL_CLOEXEC);
if (epoll_fd == -1) {
PLOG(ERROR) << "epoll_create1 failed";
exit(1);
}
signal_handler_init();
property_load_boot_defaults();
export_oem_lock_status();
start_property_service();
set_usb_controller();
const BuiltinFunctionMap function_map;
Action::set_function_map(&function_map);
Parser& parser = Parser::GetInstance();
parser.AddSectionParser("service",std::make_unique<ServiceParser>());
parser.AddSectionParser("on", std::make_unique<ActionParser>());
parser.AddSectionParser("import", std::make_unique<ImportParser>());
std::string bootscript = GetProperty("ro.boot.init_rc", "");
if (bootscript.empty()) {
parser.ParseConfig("/init.rc");
parser.set_is_system_etc_init_loaded(
parser.ParseConfig("/system/etc/init"));
parser.set_is_vendor_etc_init_loaded(
parser.ParseConfig("/vendor/etc/init"));
parser.set_is_odm_etc_init_loaded(parser.ParseConfig("/odm/etc/init"));
} else {
parser.ParseConfig(bootscript);
parser.set_is_system_etc_init_loaded(true);
parser.set_is_vendor_etc_init_loaded(true);
parser.set_is_odm_etc_init_loaded(true);
}
// Turning this on and letting the INFO logging be discarded adds 0.2s to
// Nexus 9 boot time, so it's disabled by default.
if (false) parser.DumpState();
ActionManager& am = ActionManager::GetInstance();
am.QueueEventTrigger("early-init");
// Queue an action that waits for coldboot done so we know ueventd has set up all of /dev...
am.QueueBuiltinAction(wait_for_coldboot_done_action, "wait_for_coldboot_done");
// ... so that we can start queuing up actions that require stuff from /dev.
am.QueueBuiltinAction(mix_hwrng_into_linux_rng_action, "mix_hwrng_into_linux_rng");
am.QueueBuiltinAction(set_mmap_rnd_bits_action, "set_mmap_rnd_bits");
am.QueueBuiltinAction(set_kptr_restrict_action, "set_kptr_restrict");
am.QueueBuiltinAction(keychord_init_action, "keychord_init");
am.QueueBuiltinAction(console_init_action, "console_init");
// Trigger all the boot actions to get us started.
am.QueueEventTrigger("init");
// Repeat mix_hwrng_into_linux_rng in case /dev/hw_random or /dev/random
// wasn't ready immediately after wait_for_coldboot_done
am.QueueBuiltinAction(mix_hwrng_into_linux_rng_action, "mix_hwrng_into_linux_rng");
// Don't mount filesystems or start core system services in charger mode.
std::string bootmode = GetProperty("ro.bootmode", "");
if (bootmode == "charger") {
am.QueueEventTrigger("charger");
} else {
am.QueueEventTrigger("late-init");
}
// Run all property triggers based on current state of the properties.
am.QueueBuiltinAction(queue_property_triggers_action, "queue_property_triggers");
//---------------------第七部分--------------------------------------
// 启动结束,开始守护服务(守护进程)
//----------------------------------------------------------------------
while (true) {
// By default, sleep until something happens.
int epoll_timeout_ms = -1;
if (!(waiting_for_prop || ServiceManager::GetInstance().IsWaitingForExec())) {
am.ExecuteOneCommand();
}
if (!(waiting_for_prop || ServiceManager::GetInstance().IsWaitingForExec())) {
restart_processes();
// If there's a process that needs restarting, wake up in time for that.
if (process_needs_restart_at != 0) {
epoll_timeout_ms = (process_needs_restart_at - time(nullptr)) * 1000;
if (epoll_timeout_ms < 0) epoll_timeout_ms = 0;
}
// If there's more work to do, wake up again immediately.
if (am.HasMoreCommands()) epoll_timeout_ms = 0;
}
epoll_event ev;
int nr = TEMP_FAILURE_RETRY(epoll_wait(epoll_fd, &ev, 1, epoll_timeout_ms));
if (nr == -1) {
PLOG(ERROR) << "epoll_wait failed";
} else if (nr == 1) {
((void (*)()) ev.data.ptr)();
}
}
return 0;
}参考
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