深入解析android5.1 healthd
作者:kc专栏
healthd主要是读取电池节点的信息,传给BatteryService。或者在关机充电等使用。注意healthd中使用的是kernel的log。
下面先从main函数分析
int main(int argc, char **argv) { int ch; int ret; klog_set_level(KLOG_LEVEL); healthd_mode_ops = &android_ops; if (!strcmp(basename(argv[0]), "charger")) {//解析输入参数如果是charger的使用charger_ops,这里就不做介绍 healthd_mode_ops = &charger_ops; } else { while ((ch = getopt(argc, argv, "cr")) != -1) {//分析输入命令,各个命令对应不同的charger_ops switch (ch) { case 'c': healthd_mode_ops = &charger_ops; break; case 'r': healthd_mode_ops = &recovery_ops; break; case '?': default: KLOG_ERROR(LOG_TAG, "Unrecognized healthd option: %c\n", optopt); exit(1); } } } ret = healthd_init();//healthd做初始化 if (ret) { KLOG_ERROR("Initialization failed, exiting\n"); exit(2); } healthd_mainloop();//主函数 KLOG_ERROR("Main loop terminated, exiting\n"); return 3; }
如果是正常开机,不走关机充电等,healthd_mode_ops = &android_ops;而这里面具体的函数在后面进行详细的介绍。
static struct healthd_mode_ops android_ops = { .init = healthd_mode_android_init, .preparetowait = healthd_mode_android_preparetowait, .heartbeat = healthd_mode_nop_heartbeat, .battery_update = healthd_mode_android_battery_update, };
下面分析下healthd_init函数,heathd使用了epoll进行IO复用。
static int healthd_init() { epollfd = epoll_create(MAX_EPOLL_EVENTS); if (epollfd == -1) { KLOG_ERROR(LOG_TAG, "epoll_create failed; errno=%d\n", errno); return -1; } healthd_board_init(&healthd_config); healthd_mode_ops->init(&healthd_config); wakealarm_init(); uevent_init(); gBatteryMonitor = new BatteryMonitor(); gBatteryMonitor->init(&healthd_config); return 0; }
这里的healthd_mode_ops->init的函数是android_ops 的healthd_mode_android_init函数,这里主要是将binder通信的fd也加入epoll,而不像普通binder进程最后使用IPCThreadState::self()->joinThreadPool。这样所有的fd全在epoll管理,只用了一个线程
int healthd_mode_android_preparetowait(void) { IPCThreadState::self()->flushCommands(); return -1; } static void binder_event(uint32_t /*epevents*/) { IPCThreadState::self()->handlePolledCommands(); } void healthd_mode_android_init(struct healthd_config* /*config*/) { ProcessState::self()->setThreadPoolMaxThreadCount(0); IPCThreadState::self()->disableBackgroundScheduling(true); IPCThreadState::self()->setupPolling(&gBinderFd); if (gBinderFd >= 0) { if (healthd_register_event(gBinderFd, binder_event)) KLOG_ERROR(LOG_TAG, "Register for binder events failed\n"); } gBatteryPropertiesRegistrar = new BatteryPropertiesRegistrar(); gBatteryPropertiesRegistrar->publish(); }
gBatteryPropertiesRegistrar->publish将"batteryproperties"这个Service加入到ServiceManager中
void BatteryPropertiesRegistrar::publish() { defaultServiceManager()->addService(String16("batteryproperties"), this); }
接下来再来看下wakealarm_init
static void wakealarm_init(void) { wakealarm_fd = timerfd_create(CLOCK_BOOTTIME_ALARM, TFD_NONBLOCK); if (wakealarm_fd == -1) { KLOG_ERROR(LOG_TAG, "wakealarm_init: timerfd_create failed\n"); return; } if (healthd_register_event(wakealarm_fd, wakealarm_event)) KLOG_ERROR(LOG_TAG, "Registration of wakealarm event failed\n"); wakealarm_set_interval(healthd_config.periodic_chores_interval_fast); }
wakealarm_init设置alarm唤醒的interval,再来看下时间处理函数
static void wakealarm_event(uint32_t /*epevents*/) { unsigned long long wakeups; if (read(wakealarm_fd, &wakeups, sizeof(wakeups)) == -1) {//出错结束 KLOG_ERROR(LOG_TAG, "wakealarm_event: read wakealarm fd failed\n"); return; } KLOG_ERROR(LOG_TAG, "wakealarm_event\n"); periodic_chores(); }
static void periodic_chores() { healthd_battery_update(); }
void healthd_battery_update(void) { // Fast wake interval when on charger (watch for overheat); // slow wake interval when on battery (watch for drained battery). KLOG_ERROR(LOG_TAG, "healthd_battery_update enter\n"); int new_wake_interval = gBatteryMonitor->update() ?//调用主要的update函数,根据返回值,如果当前在充电返回true healthd_config.periodic_chores_interval_fast ://时间设置1分钟 healthd_config.periodic_chores_interval_slow; KLOG_ERROR(LOG_TAG, "healthd_battery_update after\n"); if (new_wake_interval != wakealarm_wake_interval) wakealarm_set_interval(new_wake_interval); // During awake periods poll at fast rate. If wake alarm is set at fast // rate then just use the alarm; if wake alarm is set at slow rate then // poll at fast rate while awake and let alarm wake up at slow rate when // asleep. if (healthd_config.periodic_chores_interval_fast == -1) awake_poll_interval = -1; else awake_poll_interval = new_wake_interval == healthd_config.periodic_chores_interval_fast ?//当前时间是一分钟,epoll为永远阻塞,否则为1分钟 -1 : healthd_config.periodic_chores_interval_fast * 1000; }
接下来再来看看uEvent的,
static void uevent_init(void) { uevent_fd = uevent_open_socket(64*1024, true); if (uevent_fd < 0) { KLOG_ERROR(LOG_TAG, "uevent_init: uevent_open_socket failed\n"); return; } fcntl(uevent_fd, F_SETFL, O_NONBLOCK); if (healthd_register_event(uevent_fd, uevent_event)) KLOG_ERROR(LOG_TAG, "register for uevent events failed\n"); }
看看uevent_event的处理函数,获取uevent后主要判断是否是电源系统的,如果是调用healthd_battery_update函数
static void uevent_event(uint32_t /*epevents*/) { char msg[UEVENT_MSG_LEN+2]; char *cp; int n; n = uevent_kernel_multicast_recv(uevent_fd, msg, UEVENT_MSG_LEN); if (n <= 0) return; if (n >= UEVENT_MSG_LEN) /* overflow -- discard */ return; msg[n] = '\0'; msg[n+1] = '\0'; cp = msg; KLOG_ERROR(LOG_TAG, "uevent_event\n"); while (*cp) { if (!strcmp(cp, "SUBSYSTEM=" POWER_SUPPLY_SUBSYSTEM)) {//是这个子系统的调用healthd_battery_update函数 healthd_battery_update(); break; } /* advance to after the next \0 */ while (*cp++) ; } }
下面分析下healthd_mainloop这个主函数,主函数主要是epoll函数监听3个fd,有事件就处理。
static void healthd_mainloop(void) { while (1) { struct epoll_event events[eventct]; int nevents; int timeout = awake_poll_interval; int mode_timeout; mode_timeout = healthd_mode_ops->preparetowait(); if (timeout < 0 || (mode_timeout > 0 && mode_timeout < timeout)) timeout = mode_timeout; nevents = epoll_wait(epollfd, events, eventct, timeout);//epoll_wait等待各个fd的事件,timeout为超时时间 KLOG_ERROR(LOG_TAG, "kangchen healthd_mainloop epoll_wait\n"); if (nevents == -1) { if (errno == EINTR) continue; KLOG_ERROR(LOG_TAG, "healthd_mainloop: epoll_wait failed\n"); break; } for (int n = 0; n < nevents; ++n) { if (events[n].data.ptr)//遍历各个fd的事件上来,每个处理函数处理 (*(void (*)(int))events[n].data.ptr)(events[n].events); } if (!nevents)//当什么事件没有的时候,是因为epoll超时设置走下来的,这时候也要update下 periodic_chores(); healthd_mode_ops->heartbeat(); } return; }
init函数主要将healthd_config 对象传入,并且将里面的成员的一些地址信息去初始化保存起来。主要是保存一些地址信息,以及充电方式。
void BatteryMonitor::init(struct healthd_config *hc) { String8 path; char pval[PROPERTY_VALUE_MAX]; mHealthdConfig = hc;//将外面传进来的heathdconfig的指针赋给成员变量 DIR* dir = opendir(POWER_SUPPLY_SYSFS_PATH);//打开地址 /sys/class/power_supply if (dir == NULL) { KLOG_ERROR(LOG_TAG, "Could not open %s\n", POWER_SUPPLY_SYSFS_PATH); } else { struct dirent* entry; while ((entry = readdir(dir))) { const char* name = entry->d_name; if (!strcmp(name, ".") || !strcmp(name, "..")) continue; char buf[20]; // Look for "type" file in each subdirectory path.clear(); path.appendFormat("%s/%s/type", POWER_SUPPLY_SYSFS_PATH, name); switch(readPowerSupplyType(path)) {//读取各个目录下type的值,比如/sys/class/power_supply/battery 下type的值为Battery,在readPowerSupplyType读取并且转化为ANDROID_POWER_SUPPLY_TYPE_BATTERY case ANDROID_POWER_SUPPLY_TYPE_AC: if (mHealthdConfig->acChargeHeathPath.isEmpty()) { path.clear(); path.appendFormat("%s/%s/health", POWER_SUPPLY_SYSFS_PATH, name); if (access(path, R_OK) == 0) mHealthdConfig->acChargeHeathPath = path;//配置路径 } path.clear(); path.appendFormat("%s/%s/online", POWER_SUPPLY_SYSFS_PATH, name); if (access(path.string(), R_OK) == 0) mChargerNames.add(String8(name));//chargername 就是当前目录名字:ac break; case ANDROID_POWER_SUPPLY_TYPE_USB://usb 类似ac if (mHealthdConfig->usbChargeHeathPath.isEmpty()) { path.clear(); path.appendFormat("%s/%s/health", POWER_SUPPLY_SYSFS_PATH, name); if (access(path, R_OK) == 0) mHealthdConfig->usbChargeHeathPath = path; } path.clear(); path.appendFormat("%s/%s/online", POWER_SUPPLY_SYSFS_PATH, name); if (access(path.string(), R_OK) == 0) mChargerNames.add(String8(name)); break; case ANDROID_POWER_SUPPLY_TYPE_WIRELESS://类似 path.clear(); path.appendFormat("%s/%s/online", POWER_SUPPLY_SYSFS_PATH, name); if (access(path.string(), R_OK) == 0) mChargerNames.add(String8(name)); break; case ANDROID_POWER_SUPPLY_TYPE_BATTERY://battery mBatteryDevicePresent = true; if (mHealthdConfig->batteryStatusPath.isEmpty()) { path.clear(); path.appendFormat("%s/%s/status", POWER_SUPPLY_SYSFS_PATH, name); if (access(path, R_OK) == 0) mHealthdConfig->batteryStatusPath = path; } if (mHealthdConfig->batteryHealthPath.isEmpty()) { path.clear(); path.appendFormat("%s/%s/health", POWER_SUPPLY_SYSFS_PATH, name); if (access(path, R_OK) == 0) mHealthdConfig->batteryHealthPath = path; } if (mHealthdConfig->batteryPresentPath.isEmpty()) { path.clear(); path.appendFormat("%s/%s/present", POWER_SUPPLY_SYSFS_PATH, name); if (access(path, R_OK) == 0) mHealthdConfig->batteryPresentPath = path; } if (mHealthdConfig->batteryCapacityPath.isEmpty()) { path.clear(); path.appendFormat("%s/%s/capacity", POWER_SUPPLY_SYSFS_PATH, name); if (access(path, R_OK) == 0) mHealthdConfig->batteryCapacityPath = path; } if (mHealthdConfig->batteryVoltagePath.isEmpty()) { path.clear(); path.appendFormat("%s/%s/voltage_now", POWER_SUPPLY_SYSFS_PATH, name); if (access(path, R_OK) == 0) { mHealthdConfig->batteryVoltagePath = path; } else { path.clear(); path.appendFormat("%s/%s/batt_vol", POWER_SUPPLY_SYSFS_PATH, name); if (access(path, R_OK) == 0) mHealthdConfig->batteryVoltagePath = path; } } if (mHealthdConfig->batteryCurrentNowPath.isEmpty()) { path.clear(); path.appendFormat("%s/%s/current_now", POWER_SUPPLY_SYSFS_PATH, name); if (access(path, R_OK) == 0) mHealthdConfig->batteryCurrentNowPath = path; } if (mHealthdConfig->batteryCurrentAvgPath.isEmpty()) { path.clear(); path.appendFormat("%s/%s/current_avg", POWER_SUPPLY_SYSFS_PATH, name); if (access(path, R_OK) == 0) mHealthdConfig->batteryCurrentAvgPath = path; } if (mHealthdConfig->batteryChargeCounterPath.isEmpty()) { path.clear(); path.appendFormat("%s/%s/charge_counter", POWER_SUPPLY_SYSFS_PATH, name); if (access(path, R_OK) == 0) mHealthdConfig->batteryChargeCounterPath = path; } if (mHealthdConfig->batteryTemperaturePath.isEmpty()) { path.clear(); path.appendFormat("%s/%s/temp", POWER_SUPPLY_SYSFS_PATH, name); if (access(path, R_OK) == 0) { mHealthdConfig->batteryTemperaturePath = path; } else { path.clear(); path.appendFormat("%s/%s/batt_temp", POWER_SUPPLY_SYSFS_PATH, name); if (access(path, R_OK) == 0) mHealthdConfig->batteryTemperaturePath = path; } } if (mHealthdConfig->batteryTechnologyPath.isEmpty()) { path.clear(); path.appendFormat("%s/%s/technology", POWER_SUPPLY_SYSFS_PATH, name); if (access(path, R_OK) == 0) mHealthdConfig->batteryTechnologyPath = path; } break; case ANDROID_POWER_SUPPLY_TYPE_UNKNOWN: break; } } closedir(dir); } if (!mChargerNames.size()) KLOG_ERROR(LOG_TAG, "No charger supplies found\n"); if (!mBatteryDevicePresent) {//主要由battery该成员变量就为true KLOG_WARNING(LOG_TAG, "No battery devices found\n"); hc->periodic_chores_interval_fast = -1; hc->periodic_chores_interval_slow = -1; } else { if (mHealthdConfig->batteryStatusPath.isEmpty()) KLOG_WARNING(LOG_TAG, "BatteryStatusPath not found\n"); 。。。。。。。。。。。。。//这里都是一些警告 } if (property_get("ro.boot.fake_battery", pval, NULL) > 0 && strtol(pval, NULL, 10) != 0) { mBatteryFixedCapacity = FAKE_BATTERY_CAPACITY; mBatteryFixedTemperature = FAKE_BATTERY_TEMPERATURE; } }
下面就是update函数,将数据封装在BatteryProperties 中,并且通过healthd_mode_ops->battery_update把BatteryProperties 发给上层。
bool BatteryMonitor::update(void) { bool logthis; props.chargerAcOnline = false; props.chargerUsbOnline = false; props.chargerWirelessOnline = false; props.batteryStatus = BATTERY_STATUS_UNKNOWN; props.batteryHealth = BATTERY_HEALTH_UNKNOWN; //都是从之前配置的mHealthd中取地址,读取节点信息,保存到props成员变量中 if (!mHealthdConfig->batteryPresentPath.isEmpty()) props.batteryPresent = getBooleanField(mHealthdConfig->batteryPresentPath); else props.batteryPresent = mBatteryDevicePresent; props.batteryLevel = mBatteryFixedCapacity ? mBatteryFixedCapacity : getIntField(mHealthdConfig->batteryCapacityPath); props.batteryVoltage = getIntField(mHealthdConfig->batteryVoltagePath) / 1000; props.batteryTemperature = mBatteryFixedTemperature ? mBatteryFixedTemperature : getIntField(mHealthdConfig->batteryTemperaturePath); const int SIZE = 128; char buf[SIZE]; String8 btech; if (readFromFile(mHealthdConfig->batteryStatusPath, buf, SIZE) > 0) props.batteryStatus = getBatteryStatus(buf); if (readFromFile(mHealthdConfig->batteryHealthPath, buf, SIZE) > 0) props.batteryHealth = getBatteryHealth(buf); if (readFromFile(mHealthdConfig->batteryTechnologyPath, buf, SIZE) > 0) props.batteryTechnology = String8(buf); if (readFromFile(mHealthdConfig->acChargeHeathPath, buf, SIZE) > 0) props.acChargeHeath= String8(buf); if (readFromFile(mHealthdConfig->usbChargeHeathPath, buf, SIZE) > 0) props.usbChargeHeath= String8(buf); unsigned int i; for (i = 0; i < mChargerNames.size(); i++) {//遍历之前保存的各个充电方式 String8 path; path.appendFormat("%s/%s/online", POWER_SUPPLY_SYSFS_PATH, mChargerNames[i].string());//路径就是每个目录下的online字段,比如/sys/class/power_supply/usb 下的online if (readFromFile(path, buf, SIZE) > 0) { if (buf[0] != '0') {//读取online里面的内容,如果当前在usb线上充电,那么usb下online里面的内容为1 path.clear(); path.appendFormat("%s/%s/type", POWER_SUPPLY_SYSFS_PATH, mChargerNames[i].string());//这里看看是哪个type的 switch(readPowerSupplyType(path)) { case ANDROID_POWER_SUPPLY_TYPE_AC: props.chargerAcOnline = true; break; case ANDROID_POWER_SUPPLY_TYPE_USB://将其值赋成true props.chargerUsbOnline = true; break; case ANDROID_POWER_SUPPLY_TYPE_WIRELESS: props.chargerWirelessOnline = true; break; default: KLOG_WARNING(LOG_TAG, "%s: Unknown power supply type\n", mChargerNames[i].string()); } } } } logthis = !healthd_board_battery_update(&props); if (logthis) { char dmesgline[256]; if (props.batteryPresent) { snprintf(dmesgline, sizeof(dmesgline), "battery l=%d v=%d t=%s%d.%d h=%d st=%d", props.batteryLevel, props.batteryVoltage, props.batteryTemperature < 0 ? "-" : "", abs(props.batteryTemperature / 10), abs(props.batteryTemperature % 10), props.batteryHealth, props.batteryStatus); if (!mHealthdConfig->batteryCurrentNowPath.isEmpty()) { int c = getIntField(mHealthdConfig->batteryCurrentNowPath); char b[20]; snprintf(b, sizeof(b), " c=%d", c / 1000); strlcat(dmesgline, b, sizeof(dmesgline)); } } else { snprintf(dmesgline, sizeof(dmesgline), "battery none"); } KLOG_WARNING(LOG_TAG, "%s chg=%s%s%s\n", dmesgline, props.chargerAcOnline ? "a" : "", props.chargerUsbOnline ? "u" : "", props.chargerWirelessOnline ? "w" : ""); } healthd_mode_ops->battery_update(&props);//将数据传到上层的BatteryService return props.chargerAcOnline | props.chargerUsbOnline |//返回当前是否属于充电 props.chargerWirelessOnline; }
接下来看看healthd_mode_ops->battery_update是怎么把数据传到上层的
void healthd_mode_android_battery_update( struct android::BatteryProperties *props) { if (gBatteryPropertiesRegistrar != NULL) gBatteryPropertiesRegistrar->notifyListeners(*props); return; }
上层会通过binder通信,注册一个回调到BatteryPropertiesRegistrar
void BatteryPropertiesRegistrar::registerListener(const sp<IBatteryPropertiesListener>& listener) { { if (listener == NULL) return; Mutex::Autolock _l(mRegistrationLock); // check whether this is a duplicate for (size_t i = 0; i < mListeners.size(); i++) { if (mListeners[i]->asBinder() == listener->asBinder()) { return; } } mListeners.add(listener); listener->asBinder()->linkToDeath(this); } healthd_battery_update(); }
而update函数就是调用了notifyListeners遍历各个listener传到上层BatteryService
void BatteryPropertiesRegistrar::notifyListeners(struct BatteryProperties props) { Mutex::Autolock _l(mRegistrationLock); for (size_t i = 0; i < mListeners.size(); i++) { mListeners[i]->batteryPropertiesChanged(props); } }
再来看看BatteryService中,在onStart中通过ServiceManager,和batteryproperties这个Service通信,将BatteryListener这个listenter注册到batteryproperties中去
@Override public void onStart() { IBinder b = ServiceManager.getService("batteryproperties"); final IBatteryPropertiesRegistrar batteryPropertiesRegistrar = IBatteryPropertiesRegistrar.Stub.asInterface(b); try { batteryPropertiesRegistrar.registerListener(new BatteryListener()); } catch (RemoteException e) { // Should never happen. } publishBinderService("battery", new BinderService()); publishLocalService(BatteryManagerInternal.class, new LocalService()); }
再来看看BatteryListener 的batteryPropertiesChanged接口,当下面调这个接口,就会调用BatteryService的update函数,然后就是BatteryService的一些主要流程就不分析了。
private final class BatteryListener extends IBatteryPropertiesListener.Stub { @Override public void batteryPropertiesChanged(BatteryProperties props) { final long identity = Binder.clearCallingIdentity(); try { BatteryService.this.update(props); } finally { Binder.restoreCallingIdentity(identity); } } }
BatteryService接受healthd的数据都是被动的,healthd穿过来的。有没有主动去healthd查询的。
在BatteryManager中就有主动去healthd查询的,代码如下
private long queryProperty(int id) { long ret; if (mBatteryPropertiesRegistrar == null) { IBinder b = ServiceManager.getService("batteryproperties");//获取batteryproperties Service mBatteryPropertiesRegistrar = IBatteryPropertiesRegistrar.Stub.asInterface(b);//接口转化下 if (mBatteryPropertiesRegistrar == null) return Long.MIN_VALUE; } try { BatteryProperty prop = new BatteryProperty(); if (mBatteryPropertiesRegistrar.getProperty(id, prop) == 0)//prop是输出 ret = prop.getLong(); else ret = Long.MIN_VALUE; } catch (RemoteException e) { ret = Long.MIN_VALUE; } return ret; }
再到healthd看看对应的接口
status_t BatteryPropertiesRegistrar::getProperty(int id, struct BatteryProperty *val) { return healthd_get_property(id, val); }
status_t healthd_get_property(int id, struct BatteryProperty *val) { return gBatteryMonitor->getProperty(id, val); }
java的BatteryProperty对象对应到这边是指针
status_t BatteryMonitor::getProperty(int id, struct BatteryProperty *val) { status_t ret = BAD_VALUE; val->valueInt64 = LONG_MIN; switch(id) { case BATTERY_PROP_CHARGE_COUNTER://根据不同ID,返回不同值 if (!mHealthdConfig->batteryChargeCounterPath.isEmpty()) { val->valueInt64 = getIntField(mHealthdConfig->batteryChargeCounterPath); ret = NO_ERROR; } else { ret = NAME_NOT_FOUND; } break; case BATTERY_PROP_CURRENT_NOW: if (!mHealthdConfig->batteryCurrentNowPath.isEmpty()) { val->valueInt64 = getIntField(mHealthdConfig->batteryCurrentNowPath); ret = NO_ERROR; } else { ret = NAME_NOT_FOUND; } break; case BATTERY_PROP_CURRENT_AVG: if (!mHealthdConfig->batteryCurrentAvgPath.isEmpty()) { val->valueInt64 = getIntField(mHealthdConfig->batteryCurrentAvgPath); ret = NO_ERROR; } else { ret = NAME_NOT_FOUND; } break; case BATTERY_PROP_CAPACITY: if (!mHealthdConfig->batteryCapacityPath.isEmpty()) { val->valueInt64 = getIntField(mHealthdConfig->batteryCapacityPath); ret = NO_ERROR; } else { ret = NAME_NOT_FOUND; } break; case BATTERY_PROP_ENERGY_COUNTER: if (mHealthdConfig->energyCounter) { ret = mHealthdConfig->energyCounter(&val->valueInt64); } else { ret = NAME_NOT_FOUND; } break; default: break; } return ret; }
以上就是本文的全部内容,希望对大家的学习有所帮助,也希望大家多多支持脚本之家。