status_t StreamingProcessor::dump(int fd, const Vector<String16>& /*args*/) {
String8 result;
result.append(" Current requests:\n");
if (mPreviewRequest.entryCount() != 0) {
result.append(" Preview request:\n");
write(fd, result.string(), result.size());
mPreviewRequest.dump(fd, 2, 6);
result.clear();
} else {
result.append(" Preview request: undefined\n");
}
if (mRecordingRequest.entryCount() != 0) {
result = " Recording request:\n";
write(fd, result.string(), result.size());
mRecordingRequest.dump(fd, 2, 6);
result.clear();
} else {
result = " Recording request: undefined\n";
}
const char* streamTypeString[] = {
"none", "preview", "record"
};
result.append(String8::format(" Active request: %s (paused: %s)\n",
streamTypeString[mActiveRequest],
mPaused ? "yes" : "no"));
write(fd, result.string(), result.size());
return OK;
}
void HDMIAudioCaps::getChannelMasksForAF(String8& masks) {
Mutex::Autolock _l(mLock);
masks.clear();
// If the sink does not support basic audio, then it supports no audio.
if (!mBasicAudioSupported)
return;
masks.append("AUDIO_CHANNEL_OUT_STEREO");
// To keep things simple, only report mode information for the mode
// which supports the maximum number of channels.
ssize_t ndx = getMaxChModeNdx_l();
if (ndx < 0)
return;
if (mModes[ndx].max_ch >= 6) {
if (masks.length())
masks.append("|");
masks.append((mModes[ndx].max_ch >= 8)
? "AUDIO_CHANNEL_OUT_5POINT1|AUDIO_CHANNEL_OUT_7POINT1"
: "AUDIO_CHANNEL_OUT_5POINT1");
}
}
void HDMIAudioCaps::getRatesForAF(String8& rates) {
Mutex::Autolock _l(mLock);
rates.clear();
// If the sink does not support basic audio, then it supports no audio.
if (!mBasicAudioSupported)
return;
// Basic audio always supports from 32k through 38k.
uint32_t tmp = kSR_32000 | kSR_44100 | kSR_48000;
// To keep things simple, only report mode information for the PCM mode
// which supports the maximum number of channels.
ssize_t ndx = getMaxChModeNdx_l();
if (ndx >= 0)
tmp |= mModes[ndx].sr_bitmask;
bool first = true;
for (uint32_t i = 1; tmp; i <<= 1) {
if (i & tmp) {
rates.appendFormat(first ? "%d" : "|%d", srMaskToSR(i));
first = false;
tmp &= ~i;
}
}
}
void NBLog::Reader::dumpLine(const String8& timestamp, String8& body)
{
if (mFd >= 0) {
dprintf(mFd, "%.*s%s %s\n", mIndent, "", timestamp.string(), body.string());
} else {
ALOGI("%.*s%s %s", mIndent, "", timestamp.string(), body.string());
}
body.clear();
}
static bool find(String8& result,
const String8& pattern, const char* const search, bool exact) {
// in the emulator case, we just return the hardcoded name
// of the software renderer.
if (checkGlesEmulationStatus() == 0) {
ALOGD("Emulator without GPU support detected. "
"Fallback to software renderer.");
#if defined(__LP64__)
result.setTo("/system/lib64/egl/libGLES_android.so");
#else
result.setTo("/system/lib/egl/libGLES_android.so");
#endif
return true;
}
if (exact) {
String8 absolutePath;
absolutePath.appendFormat("%s/%s.so", search, pattern.string());
if (!access(absolutePath.string(), R_OK)) {
result = absolutePath;
return true;
}
return false;
}
DIR* d = opendir(search);
if (d != NULL) {
struct dirent cur;
struct dirent* e;
while (readdir_r(d, &cur, &e) == 0 && e) {
if (e->d_type == DT_DIR) {
continue;
}
if (!strcmp(e->d_name, "libGLES_android.so")) {
// always skip the software renderer
continue;
}
if (strstr(e->d_name, pattern.string()) == e->d_name) {
if (!strcmp(e->d_name + strlen(e->d_name) - 3, ".so")) {
result.clear();
result.appendFormat("%s/%s", search, e->d_name);
closedir(d);
return true;
}
}
}
closedir(d);
}
return false;
}
status_t DrmPlugin::getKeyRequest(
const Vector<uint8_t>& scope,
const Vector<uint8_t>& initData,
const String8& initDataType,
KeyType keyType,
const KeyedVector<String8, String8>& optionalParameters,
Vector<uint8_t>& request,
String8& defaultUrl) {
UNUSED(optionalParameters);
if (keyType != kKeyType_Streaming) {
return android::ERROR_DRM_CANNOT_HANDLE;
}
sp<Session> session = mSessionLibrary->findSession(scope);
defaultUrl.clear();
return session->getKeyRequest(initData, initDataType, &request);
}
static String8 find(const char* kind) {
String8 result;
String8 pattern;
pattern.appendFormat("lib%s", kind);
const char* const searchPaths[] = {
#if defined(__LP64__)
"/vendor/lib64/egl",
"/system/lib64/egl"
#else
"/vendor/lib/egl",
"/system/lib/egl"
#endif
};
// first, we search for the exact name of the GLES userspace
// driver in both locations.
// i.e.:
// libGLES.so, or:
// libEGL.so, libGLESv1_CM.so, libGLESv2.so
for (size_t i=0 ; i<NELEM(searchPaths) ; i++) {
if (find(result, pattern, searchPaths[i], true)) {
return result;
}
}
// for compatibility with the old "egl.cfg" naming convention
// we look for files that match:
// libGLES_*.so, or:
// libEGL_*.so, libGLESv1_CM_*.so, libGLESv2_*.so
pattern.append("_");
for (size_t i=0 ; i<NELEM(searchPaths) ; i++) {
if (find(result, pattern, searchPaths[i], false)) {
return result;
}
}
// we didn't find the driver. gah.
result.clear();
return result;
}
static bool find(String8& result,
const String8& pattern, const char* const search, bool exact) {
if (exact) {
String8 absolutePath;
absolutePath.appendFormat("%s/%s.so", search, pattern.string());
if (!access(absolutePath.string(), R_OK)) {
result = absolutePath;
return true;
}
return false;
}
DIR* d = opendir(search);
if (d != NULL) {
struct dirent cur;
struct dirent* e;
while (readdir_r(d, &cur, &e) == 0 && e) {
if (e->d_type == DT_DIR) {
continue;
}
if (!strcmp(e->d_name, "libGLES_android.so")) {
// always skip the software renderer
continue;
}
if (strstr(e->d_name, pattern.string()) == e->d_name) {
if (!strcmp(e->d_name + strlen(e->d_name) - 3, ".so")) {
result.clear();
result.appendFormat("%s/%s", search, e->d_name);
closedir(d);
return true;
}
}
}
closedir(d);
}
return false;
}
void BatteryMonitor::init(struct healthd_config *hc, bool nosvcmgr) {
String8 path;
mHealthdConfig = hc;
DIR* dir = opendir(POWER_SUPPLY_SYSFS_PATH);
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)) {
case ANDROID_POWER_SUPPLY_TYPE_AC:
case ANDROID_POWER_SUPPLY_TYPE_USB:
case ANDROID_POWER_SUPPLY_TYPE_WIRELESS:
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:
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->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 (mHealthdConfig->batteryStatusPath.isEmpty())
KLOG_WARNING(LOG_TAG, "BatteryStatusPath not found\n");
if (mHealthdConfig->batteryHealthPath.isEmpty())
KLOG_WARNING(LOG_TAG, "BatteryHealthPath not found\n");
if (mHealthdConfig->batteryPresentPath.isEmpty())
KLOG_WARNING(LOG_TAG, "BatteryPresentPath not found\n");
if (mHealthdConfig->batteryCapacityPath.isEmpty())
KLOG_WARNING(LOG_TAG, "BatteryCapacityPath not found\n");
if (mHealthdConfig->batteryVoltagePath.isEmpty())
KLOG_WARNING(LOG_TAG, "BatteryVoltagePath not found\n");
if (mHealthdConfig->batteryTemperaturePath.isEmpty())
KLOG_WARNING(LOG_TAG, "BatteryTemperaturePath not found\n");
if (mHealthdConfig->batteryTechnologyPath.isEmpty())
KLOG_WARNING(LOG_TAG, "BatteryTechnologyPath not found\n");
if (nosvcmgr == false) {
mBatteryPropertiesRegistrar = new BatteryPropertiesRegistrar(this);
mBatteryPropertiesRegistrar->publish();
}
}
bool BatteryMonitor::update(void) {
struct BatteryProperties props;
bool logthis;
props.chargerAcOnline = false;
props.chargerUsbOnline = false;
props.chargerWirelessOnline = false;
props.batteryStatus = BATTERY_STATUS_UNKNOWN;
props.batteryHealth = BATTERY_HEALTH_UNKNOWN;
props.batteryCurrentNow = INT_MIN;
props.batteryChargeCounter = INT_MIN;
if (!mHealthdConfig->batteryPresentPath.isEmpty())
props.batteryPresent = getBooleanField(mHealthdConfig->batteryPresentPath);
else
props.batteryPresent = true;
props.batteryLevel = getIntField(mHealthdConfig->batteryCapacityPath);
props.batteryVoltage = getIntField(mHealthdConfig->batteryVoltagePath) / 1000;
if (!mHealthdConfig->batteryCurrentNowPath.isEmpty())
props.batteryCurrentNow = getIntField(mHealthdConfig->batteryCurrentNowPath);
if (!mHealthdConfig->batteryChargeCounterPath.isEmpty())
props.batteryChargeCounter = getIntField(mHealthdConfig->batteryChargeCounterPath);
props.batteryTemperature = 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);
unsigned int i;
for (i = 0; i < mChargerNames.size(); i++) {
String8 path;
path.appendFormat("%s/%s/online", POWER_SUPPLY_SYSFS_PATH,
mChargerNames[i].string());
if (readFromFile(path, buf, SIZE) > 0) {
if (buf[0] != '0') {
path.clear();
path.appendFormat("%s/%s/type", POWER_SUPPLY_SYSFS_PATH,
mChargerNames[i].string());
switch(readPowerSupplyType(path)) {
case ANDROID_POWER_SUPPLY_TYPE_AC:
props.chargerAcOnline = true;
break;
case ANDROID_POWER_SUPPLY_TYPE_USB:
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];
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()) {
char b[20];
snprintf(b, sizeof(b), " c=%d", props.batteryCurrentNow / 1000);
strlcat(dmesgline, b, sizeof(dmesgline));
}
KLOG_INFO(LOG_TAG, "%s chg=%s%s%s\n", dmesgline,
props.chargerAcOnline ? "a" : "",
props.chargerUsbOnline ? "u" : "",
props.chargerWirelessOnline ? "w" : "");
}
char prop[PROP_VALUE_MAX];
// always report AC plug-in and capacity 100% if emulated.battery is set to 1
property_get("sys.emulated.battery", prop, "0");
if (!strcmp(prop, "1")) {
props.chargerAcOnline = true;
props.batteryLevel = 100;
props.chargerWirelessOnline = false;
}
if (mBatteryPropertiesRegistrar != NULL)
mBatteryPropertiesRegistrar->notifyListeners(props);
if (!strcmp(prop, "1")) {
return false;
} else {
if (0 == props.batteryTemperature)
return false;
else
return props.chargerAcOnline | props.chargerUsbOnline |
props.chargerWirelessOnline;
}
}
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;
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);
unsigned int i;
for (i = 0; i < mChargerNames.size(); i++) {
String8 path;
path.appendFormat("%s/%s/online", POWER_SUPPLY_SYSFS_PATH,
mChargerNames[i].string());
if (readFromFile(path, buf, SIZE) > 0) {
if (buf[0] != '0') {
path.clear();
path.appendFormat("%s/%s/type", POWER_SUPPLY_SYSFS_PATH,
mChargerNames[i].string());
switch(readPowerSupplyType(path)) {
case ANDROID_POWER_SUPPLY_TYPE_AC:
props.chargerAcOnline = true;
break;
case ANDROID_POWER_SUPPLY_TYPE_USB:
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");
}
size_t len = strlen(dmesgline);
snprintf(dmesgline + len, sizeof(dmesgline) - len, " chg=%s%s%s",
props.chargerAcOnline ? "a" : "",
props.chargerUsbOnline ? "u" : "",
props.chargerWirelessOnline ? "w" : "");
log_time realtime(CLOCK_REALTIME);
time_t t = realtime.tv_sec;
struct tm *tmp = gmtime(&t);
if (tmp) {
static const char fmt[] = " %Y-%m-%d %H:%M:%S.XXXXXXXXX UTC";
len = strlen(dmesgline);
if ((len < (sizeof(dmesgline) - sizeof(fmt) - 8)) // margin
&& strftime(dmesgline + len, sizeof(dmesgline) - len,
fmt, tmp)) {
char *usec = strchr(dmesgline + len, 'X');
if (usec) {
len = usec - dmesgline;
snprintf(dmesgline + len, sizeof(dmesgline) - len,
"%09u", realtime.tv_nsec);
usec[9] = ' ';
}
}
}
KLOG_WARNING(LOG_TAG, "%s\n", dmesgline);
}
healthd_mode_ops->battery_update(&props);
return props.chargerAcOnline | props.chargerUsbOnline |
props.chargerWirelessOnline;
}
void BatteryMonitor::init(struct healthd_config *hc) {
String8 path;
char pval[PROPERTY_VALUE_MAX];
mHealthdConfig = hc;
DIR* dir = opendir(POWER_SUPPLY_SYSFS_PATH);
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)) {
case ANDROID_POWER_SUPPLY_TYPE_AC:
case ANDROID_POWER_SUPPLY_TYPE_USB:
case ANDROID_POWER_SUPPLY_TYPE_WIRELESS:
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:
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) {
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");
if (mHealthdConfig->batteryHealthPath.isEmpty())
KLOG_WARNING(LOG_TAG, "BatteryHealthPath not found\n");
if (mHealthdConfig->batteryPresentPath.isEmpty())
KLOG_WARNING(LOG_TAG, "BatteryPresentPath not found\n");
if (mHealthdConfig->batteryCapacityPath.isEmpty())
KLOG_WARNING(LOG_TAG, "BatteryCapacityPath not found\n");
if (mHealthdConfig->batteryVoltagePath.isEmpty())
KLOG_WARNING(LOG_TAG, "BatteryVoltagePath not found\n");
if (mHealthdConfig->batteryTemperaturePath.isEmpty())
KLOG_WARNING(LOG_TAG, "BatteryTemperaturePath not found\n");
if (mHealthdConfig->batteryTechnologyPath.isEmpty())
KLOG_WARNING(LOG_TAG, "BatteryTechnologyPath not found\n");
}
if (property_get("ro.boot.fake_battery", pval, NULL) > 0
&& strtol(pval, NULL, 10) != 0) {
mBatteryFixedCapacity = FAKE_BATTERY_CAPACITY;
mBatteryFixedTemperature = FAKE_BATTERY_TEMPERATURE;
}
}
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;
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);
// reinitialize the mChargerNames vector everytime there is an update
String8 path;
DIR* dir = opendir(POWER_SUPPLY_SYSFS_PATH);
if (dir == NULL) {
KLOG_ERROR(LOG_TAG, "Could not open %s\n", POWER_SUPPLY_SYSFS_PATH);
} else {
struct dirent* entry;
// reconstruct the charger strings
mChargerNames.clear();
while ((entry = readdir(dir))) {
const char* name = entry->d_name;
if (!strcmp(name, ".") || !strcmp(name, ".."))
continue;
// Look for "type" file in each subdirectory
path.clear();
path.appendFormat("%s/%s/type", POWER_SUPPLY_SYSFS_PATH, name);
switch(readPowerSupplyType(path)) {
case ANDROID_POWER_SUPPLY_TYPE_BATTERY:
break;
default:
path.clear();
path.appendFormat("%s/%s/online", POWER_SUPPLY_SYSFS_PATH, name);
if (access(path.string(), R_OK) == 0) {
mChargerNames.add(String8(name));
if (readFromFile(path, buf, SIZE) > 0) {
if (buf[0] != '0') {
path.clear();
path.appendFormat("%s/%s/type", POWER_SUPPLY_SYSFS_PATH,
name);
switch(readPowerSupplyType(path)) {
case ANDROID_POWER_SUPPLY_TYPE_AC:
props.chargerAcOnline = true;
break;
case ANDROID_POWER_SUPPLY_TYPE_USB:
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",
name);
}
}
}
}
break;
} //switch
} //while
closedir(dir);
}//else
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);
return props.chargerAcOnline | props.chargerUsbOnline |
props.chargerWirelessOnline;
}
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;
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);
unsigned int i;
for (i = 0; i < mChargerNames.size(); i++) {
String8 path;
path.appendFormat("%s/%s/online", POWER_SUPPLY_SYSFS_PATH,
mChargerNames[i].string());
if (readFromFile(path, buf, SIZE) > 0) {
if (buf[0] != '0') {
path.clear();
path.appendFormat("%s/%s/type", POWER_SUPPLY_SYSFS_PATH,
mChargerNames[i].string());
switch(readPowerSupplyType(path)) {
case ANDROID_POWER_SUPPLY_TYPE_AC:
props.chargerAcOnline = true;
break;
case ANDROID_POWER_SUPPLY_TYPE_USB:
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);
return props.chargerAcOnline | props.chargerUsbOnline |
props.chargerWirelessOnline;
}
static String8 find(const char* kind) {
String8 result;
int emulationStatus = checkGlesEmulationStatus();
switch (emulationStatus) {
case 0:
#if defined(__LP64__)
result.setTo("/system/lib64/egl/libGLES_android.so");
#else
result.setTo("/system/lib/egl/libGLES_android.so");
#endif
return result;
case 1:
// Use host-side OpenGL through the "emulation" library
#if defined(__LP64__)
result.appendFormat("/system/lib64/egl/lib%s_emulation.so", kind);
#else
result.appendFormat("/system/lib/egl/lib%s_emulation.so", kind);
#endif
return result;
default:
// Not in emulator, or use other guest-side implementation
break;
}
String8 pattern;
pattern.appendFormat("lib%s", kind);
const char* const searchPaths[] = {
#if defined(__LP64__)
"/vendor/lib64/egl",
"/system/lib64/egl"
#else
"/vendor/lib/egl",
"/system/lib/egl"
#endif
};
// first, we search for the exact name of the GLES userspace
// driver in both locations.
// i.e.:
// libGLES.so, or:
// libEGL.so, libGLESv1_CM.so, libGLESv2.so
for (size_t i=0 ; i<NELEM(searchPaths) ; i++) {
if (find(result, pattern, searchPaths[i], true)) {
return result;
}
}
// for compatibility with the old "egl.cfg" naming convention
// we look for files that match:
// libGLES_*.so, or:
// libEGL_*.so, libGLESv1_CM_*.so, libGLESv2_*.so
pattern.append("_");
for (size_t i=0 ; i<NELEM(searchPaths) ; i++) {
if (find(result, pattern, searchPaths[i], false)) {
return result;
}
}
// we didn't find the driver. gah.
result.clear();
return result;
}
static void android_server_BatteryService_update(JNIEnv* env, jobject obj)
{
setBooleanField(env, obj, gPaths.batteryPresentPath, gFieldIds.mBatteryPresent);
setIntFieldMax(env, obj, gPaths.batteryCapacityPath, gFieldIds.mBatteryLevel, 100);
setVoltageField(env, obj, gPaths.batteryVoltagePath, gFieldIds.mBatteryVoltage);
setIntField(env, obj, gPaths.batteryTemperaturePath, gFieldIds.mBatteryTemperature);
const int SIZE = 128;
char buf[SIZE];
if (readFromFile(gPaths.batteryStatusPath, buf, SIZE) > 0)
env->SetIntField(obj, gFieldIds.mBatteryStatus, getBatteryStatus(buf));
else
env->SetIntField(obj, gFieldIds.mBatteryStatus,
gConstants.statusUnknown);
if (readFromFile(gPaths.batteryHealthPath, buf, SIZE) > 0)
env->SetIntField(obj, gFieldIds.mBatteryHealth, getBatteryHealth(buf));
if (readFromFile(gPaths.batteryTechnologyPath, buf, SIZE) > 0)
env->SetObjectField(obj, gFieldIds.mBatteryTechnology, env->NewStringUTF(buf));
unsigned int i;
String8 path;
jboolean acOnline = false;
jboolean usbOnline = false;
jboolean wirelessOnline = false;
for (i = 0; i < gChargerNames.size(); i++) {
path.clear();
path.appendFormat("%s/%s/online", POWER_SUPPLY_PATH,
gChargerNames[i].string());
if (readFromFile(path, buf, SIZE) > 0) {
if (buf[0] != '0') {
path.clear();
path.appendFormat("%s/%s/type", POWER_SUPPLY_PATH,
gChargerNames[i].string());
switch(readPowerSupplyType(path)) {
case ANDROID_POWER_SUPPLY_TYPE_AC:
acOnline = true;
break;
case ANDROID_POWER_SUPPLY_TYPE_USB:
usbOnline = true;
break;
case ANDROID_POWER_SUPPLY_TYPE_WIRELESS:
wirelessOnline = true;
break;
default:
ALOGW("%s: Unknown power supply type",
gChargerNames[i].string());
}
}
}
}
env->SetBooleanField(obj, gFieldIds.mAcOnline, acOnline);
env->SetBooleanField(obj, gFieldIds.mUsbOnline, usbOnline);
env->SetBooleanField(obj, gFieldIds.mWirelessOnline, wirelessOnline);
}
void HDMIAudioCaps::getFmtsForAF(String8& fmts) {
Mutex::Autolock _l(mLock);
fmts.clear();
// If the sink does not support basic audio, then it supports no audio.
if (!mBasicAudioSupported) {
ALOGI("ALSAFORMATS: basic audio not supported");
return;
}
fmts.append("AUDIO_FORMAT_PCM_16_BIT");
// TODO: when we can start to expect 20 and 24 bit audio modes coming from
// AF, we need to implement support to enumerate those modes.
// These names must match formats in android.media.AudioFormat
for (size_t i = 0; i < mModes.size(); ++i) {
switch (mModes[i].fmt) {
case kFmtAC3:
fmts.append("|AUDIO_FORMAT_AC3");
break;
case kFmtEAC3:
fmts.append("|AUDIO_FORMAT_E_AC3");
break;
default:
break;
}
}
#if ALSA_UTILS_PRINT_FORMATS
ALOGI("ALSAFORMATS: formats = %s", fmts.string());
for (size_t i = 0; i < mModes.size(); ++i) {
ALOGI("ALSAFORMATS: ------- fmt[%d] = 0x%08X = %s",
i, mModes[i].fmt, fmtToString(mModes[i].fmt));
ALOGI("ALSAFORMATS: comp_bitrate[%d] = 0x%08X = %d",
i, mModes[i].comp_bitrate, mModes[i].comp_bitrate);
ALOGI("ALSAFORMATS: max_ch[%d] = 0x%08X = %d",
i, mModes[i].max_ch, mModes[i].max_ch);
ALOGI("ALSAFORMATS: bps_bitmask[%d] = 0x%08X", i, mModes[i].bps_bitmask);
uint32_t bpsm = mModes[i].bps_bitmask;
while(bpsm) {
uint32_t bpsm_next = bpsm & (bpsm - 1);
uint32_t bpsm_single = bpsm ^ bpsm_next;
if (bpsm_single) {
ALOGI("ALSAFORMATS: bits = %d", bpsMaskToBPS(bpsm_single));
}
bpsm = bpsm_next;
}
ALOGI("ALSAFORMATS: sr_bitmask[%d] = 0x%08X", i, mModes[i].sr_bitmask);
uint32_t srs = mModes[i].sr_bitmask;
while(srs) {
uint32_t srs_next = srs & (srs - 1);
uint32_t srs_single = srs ^ srs_next;
if (srs_single) {
ALOGI("ALSAFORMATS: srate = %d", srMaskToSR(srs_single));
}
srs = srs_next;
}
}
#endif /* ALSA_UTILS_PRINT_FORMATS */
}
int register_android_server_BatteryService(JNIEnv* env)
{
String8 path;
struct dirent* entry;
DIR* dir = opendir(POWER_SUPPLY_PATH);
if (dir == NULL) {
ALOGE("Could not open %s\n", POWER_SUPPLY_PATH);
} else {
while ((entry = readdir(dir))) {
const char* name = entry->d_name;
// ignore "." and ".."
if (name[0] == '.' && (name[1] == 0 || (name[1] == '.' && name[2] == 0))) {
continue;
}
char buf[20];
// Look for "type" file in each subdirectory
path.clear();
path.appendFormat("%s/%s/type", POWER_SUPPLY_PATH, name);
switch(readPowerSupplyType(path)) {
case ANDROID_POWER_SUPPLY_TYPE_AC:
case ANDROID_POWER_SUPPLY_TYPE_USB:
case ANDROID_POWER_SUPPLY_TYPE_WIRELESS:
path.clear();
path.appendFormat("%s/%s/online", POWER_SUPPLY_PATH, name);
if (access(path.string(), R_OK) == 0)
gChargerNames.add(String8(name));
break;
case ANDROID_POWER_SUPPLY_TYPE_BATTERY:
path.clear();
path.appendFormat("%s/%s/status", POWER_SUPPLY_PATH, name);
if (access(path, R_OK) == 0)
gPaths.batteryStatusPath = path;
path.clear();
path.appendFormat("%s/%s/health", POWER_SUPPLY_PATH, name);
if (access(path, R_OK) == 0)
gPaths.batteryHealthPath = path;
path.clear();
path.appendFormat("%s/%s/present", POWER_SUPPLY_PATH, name);
if (access(path, R_OK) == 0)
gPaths.batteryPresentPath = path;
path.clear();
/* For some weird, unknown reason Motorola phones provide
* capacity information only in 10% steps in the 'capacity'
* file. The 'charge_counter' file provides the 1% steps
* on those phones. Since using charge_counter has issues
* on some devices, we'll use ro.product.use_charge_counter
* in build.prop to decide which capacity file to use.
*/
char valueChargeCounter[PROPERTY_VALUE_MAX];
if (property_get("ro.product.use_charge_counter", valueChargeCounter, NULL)
&& (!strcmp(valueChargeCounter, "1"))) {
path.appendFormat("%s/%s/charge_counter", POWER_SUPPLY_PATH, name);
if (access(path, R_OK) == 0)
gPaths.batteryCapacityPath = path;
} else {
path.appendFormat("%s/%s/capacity", POWER_SUPPLY_PATH, name);
if (access(path, R_OK) == 0)
gPaths.batteryCapacityPath = path;
}
path.clear();
path.appendFormat("%s/%s/voltage_now", POWER_SUPPLY_PATH, name);
if (access(path, R_OK) == 0) {
gPaths.batteryVoltagePath = path;
// voltage_now is in microvolts, not millivolts
gVoltageDivisor = 1000;
} else {
path.clear();
path.appendFormat("%s/%s/batt_vol", POWER_SUPPLY_PATH, name);
if (access(path, R_OK) == 0)
gPaths.batteryVoltagePath = path;
}
path.clear();
path.appendFormat("%s/%s/temp", POWER_SUPPLY_PATH, name);
if (access(path, R_OK) == 0) {
gPaths.batteryTemperaturePath = path;
} else {
path.clear();
path.appendFormat("%s/%s/batt_temp", POWER_SUPPLY_PATH, name);
if (access(path, R_OK) == 0)
gPaths.batteryTemperaturePath = path;
}
path.clear();
path.appendFormat("%s/%s/technology", POWER_SUPPLY_PATH, name);
if (access(path, R_OK) == 0)
gPaths.batteryTechnologyPath = path;
break;
}
}
closedir(dir);
}
if (!gChargerNames.size())
ALOGE("No charger supplies found");
if (!gPaths.batteryStatusPath)
ALOGE("batteryStatusPath not found");
if (!gPaths.batteryHealthPath)
ALOGE("batteryHealthPath not found");
if (!gPaths.batteryPresentPath)
ALOGE("batteryPresentPath not found");
if (!gPaths.batteryCapacityPath)
ALOGE("batteryCapacityPath not found");
if (!gPaths.batteryVoltagePath)
ALOGE("batteryVoltagePath not found");
if (!gPaths.batteryTemperaturePath)
ALOGE("batteryTemperaturePath not found");
if (!gPaths.batteryTechnologyPath)
ALOGE("batteryTechnologyPath not found");
jclass clazz = env->FindClass("com/android/server/BatteryService");
if (clazz == NULL) {
ALOGE("Can't find com/android/server/BatteryService");
return -1;
}
gFieldIds.mAcOnline = env->GetFieldID(clazz, "mAcOnline", "Z");
gFieldIds.mUsbOnline = env->GetFieldID(clazz, "mUsbOnline", "Z");
gFieldIds.mWirelessOnline = env->GetFieldID(clazz, "mWirelessOnline", "Z");
gFieldIds.mBatteryStatus = env->GetFieldID(clazz, "mBatteryStatus", "I");
gFieldIds.mBatteryHealth = env->GetFieldID(clazz, "mBatteryHealth", "I");
gFieldIds.mBatteryPresent = env->GetFieldID(clazz, "mBatteryPresent", "Z");
gFieldIds.mBatteryLevel = env->GetFieldID(clazz, "mBatteryLevel", "I");
gFieldIds.mBatteryTechnology = env->GetFieldID(clazz, "mBatteryTechnology", "Ljava/lang/String;");
gFieldIds.mBatteryVoltage = env->GetFieldID(clazz, "mBatteryVoltage", "I");
gFieldIds.mBatteryTemperature = env->GetFieldID(clazz, "mBatteryTemperature", "I");
LOG_FATAL_IF(gFieldIds.mAcOnline == NULL, "Unable to find BatteryService.AC_ONLINE_PATH");
LOG_FATAL_IF(gFieldIds.mUsbOnline == NULL, "Unable to find BatteryService.USB_ONLINE_PATH");
LOG_FATAL_IF(gFieldIds.mWirelessOnline == NULL, "Unable to find BatteryService.WIRELESS_ONLINE_PATH");
LOG_FATAL_IF(gFieldIds.mBatteryStatus == NULL, "Unable to find BatteryService.BATTERY_STATUS_PATH");
LOG_FATAL_IF(gFieldIds.mBatteryHealth == NULL, "Unable to find BatteryService.BATTERY_HEALTH_PATH");
LOG_FATAL_IF(gFieldIds.mBatteryPresent == NULL, "Unable to find BatteryService.BATTERY_PRESENT_PATH");
LOG_FATAL_IF(gFieldIds.mBatteryLevel == NULL, "Unable to find BatteryService.BATTERY_CAPACITY_PATH");
LOG_FATAL_IF(gFieldIds.mBatteryVoltage == NULL, "Unable to find BatteryService.BATTERY_VOLTAGE_PATH");
LOG_FATAL_IF(gFieldIds.mBatteryTemperature == NULL, "Unable to find BatteryService.BATTERY_TEMPERATURE_PATH");
LOG_FATAL_IF(gFieldIds.mBatteryTechnology == NULL, "Unable to find BatteryService.BATTERY_TECHNOLOGY_PATH");
clazz = env->FindClass("android/os/BatteryManager");
if (clazz == NULL) {
ALOGE("Can't find android/os/BatteryManager");
return -1;
}
gConstants.statusUnknown = env->GetStaticIntField(clazz,
env->GetStaticFieldID(clazz, "BATTERY_STATUS_UNKNOWN", "I"));
gConstants.statusCharging = env->GetStaticIntField(clazz,
env->GetStaticFieldID(clazz, "BATTERY_STATUS_CHARGING", "I"));
gConstants.statusDischarging = env->GetStaticIntField(clazz,
env->GetStaticFieldID(clazz, "BATTERY_STATUS_DISCHARGING", "I"));
gConstants.statusNotCharging = env->GetStaticIntField(clazz,
env->GetStaticFieldID(clazz, "BATTERY_STATUS_NOT_CHARGING", "I"));
gConstants.statusFull = env->GetStaticIntField(clazz,
env->GetStaticFieldID(clazz, "BATTERY_STATUS_FULL", "I"));
gConstants.healthUnknown = env->GetStaticIntField(clazz,
env->GetStaticFieldID(clazz, "BATTERY_HEALTH_UNKNOWN", "I"));
gConstants.healthGood = env->GetStaticIntField(clazz,
env->GetStaticFieldID(clazz, "BATTERY_HEALTH_GOOD", "I"));
gConstants.healthOverheat = env->GetStaticIntField(clazz,
env->GetStaticFieldID(clazz, "BATTERY_HEALTH_OVERHEAT", "I"));
gConstants.healthDead = env->GetStaticIntField(clazz,
env->GetStaticFieldID(clazz, "BATTERY_HEALTH_DEAD", "I"));
gConstants.healthOverVoltage = env->GetStaticIntField(clazz,
env->GetStaticFieldID(clazz, "BATTERY_HEALTH_OVER_VOLTAGE", "I"));
gConstants.healthUnspecifiedFailure = env->GetStaticIntField(clazz,
env->GetStaticFieldID(clazz, "BATTERY_HEALTH_UNSPECIFIED_FAILURE", "I"));
gConstants.healthCold = env->GetStaticIntField(clazz,
env->GetStaticFieldID(clazz, "BATTERY_HEALTH_COLD", "I"));
return jniRegisterNativeMethods(env, "com/android/server/BatteryService", sMethods, NELEM(sMethods));
}
static void CameraMetadata_dump(JNIEnv *env, jobject thiz) {
ALOGV("%s", __FUNCTION__);
CameraMetadata* metadata = CameraMetadata_getPointerThrow(env, thiz);
if (metadata == NULL) {
return;
}
/*
* Create a socket pair for local streaming read/writes.
*
* The metadata will be dumped into the write side,
* and then read back out (and logged) via the read side.
*/
int writeFd, readFd;
{
int sv[2];
if (socketpair(AF_LOCAL, SOCK_STREAM, /*protocol*/0, &sv[0]) < 0) {
jniThrowExceptionFmt(env, "java/io/IOException",
"Failed to create socketpair (errno = %#x, message = '%s')",
errno, strerror(errno));
return;
}
writeFd = sv[0];
readFd = sv[1];
}
/*
* Create a thread for doing the writing.
*
* The reading and writing must be concurrent, otherwise
* the write will block forever once it exhausts the capped
* buffer size (from getsockopt).
*/
pthread_t writeThread;
DumpMetadataParams params = {
writeFd,
metadata
};
{
int threadRet = pthread_create(&writeThread, /*attr*/NULL,
CameraMetadata_writeMetadataThread, (void*)¶ms);
if (threadRet != 0) {
close(writeFd);
jniThrowExceptionFmt(env, "java/io/IOException",
"Failed to create thread for writing (errno = %#x, message = '%s')",
threadRet, strerror(threadRet));
}
}
/*
* Read out a byte until stream is complete. Write completed lines
* to ALOG.
*/
{
char out[] = {'\0', '\0'}; // large enough to append as a string
String8 logLine;
// Read one byte at a time! Very slow but avoids complicated \n scanning.
ssize_t res;
while ((res = TEMP_FAILURE_RETRY(read(readFd, &out[0], /*count*/1))) > 0) {
if (out[0] == '\n') {
ALOGD("%s", logLine.string());
logLine.clear();
} else {
logLine.append(out);
}
}
if (res < 0) {
jniThrowExceptionFmt(env, "java/io/IOException",
"Failed to read from fd (errno = %#x, message = '%s')",
errno, strerror(errno));
//return;
} else if (!logLine.isEmpty()) {
ALOGD("%s", logLine.string());
}
}
int res;
// Join until thread finishes. Ensures params/metadata is valid until then.
if ((res = pthread_join(writeThread, /*retval*/NULL)) != 0) {
ALOGE("%s: Failed to join thread (errno = %#x, message = '%s')",
__FUNCTION__, res, strerror(res));
}
}
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;
props.maxChargingCurrent = 0;
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;
if (!mHealthdConfig->batteryCurrentNowPath.isEmpty())
props.batteryCurrent = getIntField(mHealthdConfig->batteryCurrentNowPath) / 1000;
if (!mHealthdConfig->batteryFullChargePath.isEmpty())
props.batteryFullCharge = getIntField(mHealthdConfig->batteryFullChargePath);
if (!mHealthdConfig->batteryCycleCountPath.isEmpty())
props.batteryCycleCount = getIntField(mHealthdConfig->batteryCycleCountPath);
props.batteryTemperature = mBatteryFixedTemperature ?
mBatteryFixedTemperature :
getIntField(mHealthdConfig->batteryTemperaturePath);
// For devices which do not have battery and are always plugged
// into power souce.
if (mAlwaysPluggedDevice) {
props.chargerAcOnline = true;
props.batteryPresent = true;
props.batteryStatus = BATTERY_STATUS_CHARGING;
props.batteryHealth = BATTERY_HEALTH_GOOD;
}
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);
unsigned int i;
for (i = 0; i < mChargerNames.size(); i++) {
String8 path;
path.appendFormat("%s/%s/online", POWER_SUPPLY_SYSFS_PATH,
mChargerNames[i].string());
if (readFromFile(path, buf, SIZE) > 0) {
if (buf[0] != '0') {
path.clear();
path.appendFormat("%s/%s/type", POWER_SUPPLY_SYSFS_PATH,
mChargerNames[i].string());
switch(readPowerSupplyType(path)) {
case ANDROID_POWER_SUPPLY_TYPE_AC:
props.chargerAcOnline = true;
break;
case ANDROID_POWER_SUPPLY_TYPE_USB:
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());
}
path.clear();
path.appendFormat("%s/%s/current_max", POWER_SUPPLY_SYSFS_PATH,
mChargerNames[i].string());
if (access(path.string(), R_OK) == 0) {
int maxChargingCurrent = getIntField(path);
if (props.maxChargingCurrent < maxChargingCurrent) {
props.maxChargingCurrent = maxChargingCurrent;
}
}
}
}
}
logthis = !healthd_board_battery_update(&props);
if (logthis) {
char dmesgline[256];
size_t len;
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);
len = strlen(dmesgline);
if (!mHealthdConfig->batteryCurrentNowPath.isEmpty()) {
len += snprintf(dmesgline + len, sizeof(dmesgline) - len,
" c=%d", props.batteryCurrent);
}
if (!mHealthdConfig->batteryFullChargePath.isEmpty()) {
len += snprintf(dmesgline + len, sizeof(dmesgline) - len,
" fc=%d", props.batteryFullCharge);
}
if (!mHealthdConfig->batteryCycleCountPath.isEmpty()) {
len += snprintf(dmesgline + len, sizeof(dmesgline) - len,
" cc=%d", props.batteryCycleCount);
}
} else {
snprintf(dmesgline, sizeof(dmesgline),
"battery none");
}
len = strlen(dmesgline);
snprintf(dmesgline + len, sizeof(dmesgline) - len, " chg=%s%s%s",
props.chargerAcOnline ? "a" : "",
props.chargerUsbOnline ? "u" : "",
props.chargerWirelessOnline ? "w" : "");
KLOG_WARNING(LOG_TAG, "%s\n", dmesgline);
}
healthd_mode_ops->battery_update(&props);
return props.chargerAcOnline | props.chargerUsbOnline |
props.chargerWirelessOnline;
}
