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/*
* Copyright (C) 2013 The Android Open Source Project
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#define LOG_TAG "healthd"
#include <healthd/healthd.h>
#include <healthd/BatteryMonitor.h>
#include <dirent.h>
#include <errno.h>
#include <fcntl.h>
#include <stdio.h>
#include <stdlib.h>
#include <sys/types.h>
#include <unistd.h>
#include <algorithm>
#include <memory>
#include <optional>
#include <android-base/file.h>
#include <android-base/parseint.h>
#include <android-base/strings.h>
#include <android/hardware/health/2.1/types.h>
#include <batteryservice/BatteryService.h>
#include <cutils/klog.h>
#include <cutils/properties.h>
#include <utils/Errors.h>
#include <utils/String8.h>
#include <utils/Vector.h>
#define POWER_SUPPLY_SUBSYSTEM "power_supply"
#define POWER_SUPPLY_SYSFS_PATH "/sys/class/" POWER_SUPPLY_SUBSYSTEM
#define FAKE_BATTERY_CAPACITY 42
#define FAKE_BATTERY_TEMPERATURE 424
#define MILLION 1.0e6
#define DEFAULT_VBUS_VOLTAGE 5000000
using HealthInfo_1_0 = android::hardware::health::V1_0::HealthInfo;
using HealthInfo_2_0 = android::hardware::health::V2_0::HealthInfo;
using HealthInfo_2_1 = android::hardware::health::V2_1::HealthInfo;
using android::hardware::health::V1_0::BatteryHealth;
using android::hardware::health::V1_0::BatteryStatus;
using android::hardware::health::V2_1::BatteryCapacityLevel;
using android::hardware::health::V2_1::Constants;
namespace android {
template <typename T>
struct SysfsStringEnumMap {
const char* s;
T val;
};
template <typename T>
static std::optional<T> mapSysfsString(const char* str, SysfsStringEnumMap<T> map[]) {
for (int i = 0; map[i].s; i++)
if (!strcmp(str, map[i].s))
return map[i].val;
return std::nullopt;
}
static void initHealthInfo(HealthInfo_2_1* health_info_2_1) {
*health_info_2_1 = HealthInfo_2_1{};
// HIDL enum values are zero initialized, so they need to be initialized
// properly.
health_info_2_1->batteryCapacityLevel = BatteryCapacityLevel::UNKNOWN;
health_info_2_1->batteryChargeTimeToFullNowSeconds =
(int64_t)Constants::BATTERY_CHARGE_TIME_TO_FULL_NOW_SECONDS_UNSUPPORTED;
auto* props = &health_info_2_1->legacy.legacy;
props->batteryStatus = BatteryStatus::UNKNOWN;
props->batteryHealth = BatteryHealth::UNKNOWN;
}
BatteryMonitor::BatteryMonitor()
: mHealthdConfig(nullptr),
mBatteryDevicePresent(false),
mBatteryFixedCapacity(0),
mBatteryFixedTemperature(0),
mHealthInfo(std::make_unique<HealthInfo_2_1>()) {
initHealthInfo(mHealthInfo.get());
}
BatteryMonitor::~BatteryMonitor() {}
const HealthInfo_1_0& BatteryMonitor::getHealthInfo_1_0() const {
return getHealthInfo_2_0().legacy;
}
const HealthInfo_2_0& BatteryMonitor::getHealthInfo_2_0() const {
return getHealthInfo_2_1().legacy;
}
const HealthInfo_2_1& BatteryMonitor::getHealthInfo_2_1() const {
return *mHealthInfo;
}
BatteryStatus getBatteryStatus(const char* status) {
static SysfsStringEnumMap<BatteryStatus> batteryStatusMap[] = {
{"Unknown", BatteryStatus::UNKNOWN},
{"Charging", BatteryStatus::CHARGING},
{"Discharging", BatteryStatus::DISCHARGING},
{"Not charging", BatteryStatus::NOT_CHARGING},
{"Full", BatteryStatus::FULL},
{NULL, BatteryStatus::UNKNOWN},
};
auto ret = mapSysfsString(status, batteryStatusMap);
if (!ret) {
KLOG_WARNING(LOG_TAG, "Unknown battery status '%s'\n", status);
*ret = BatteryStatus::UNKNOWN;
}
return *ret;
}
BatteryCapacityLevel getBatteryCapacityLevel(const char* capacityLevel) {
static SysfsStringEnumMap<BatteryCapacityLevel> batteryCapacityLevelMap[] = {
{"Unknown", BatteryCapacityLevel::UNKNOWN},
{"Critical", BatteryCapacityLevel::CRITICAL},
{"Low", BatteryCapacityLevel::LOW},
{"Normal", BatteryCapacityLevel::NORMAL},
{"High", BatteryCapacityLevel::HIGH},
{"Full", BatteryCapacityLevel::FULL},
{NULL, BatteryCapacityLevel::UNSUPPORTED},
};
auto ret = mapSysfsString(capacityLevel, batteryCapacityLevelMap);
if (!ret) {
KLOG_WARNING(LOG_TAG, "Unsupported battery capacity level '%s'\n", capacityLevel);
*ret = BatteryCapacityLevel::UNSUPPORTED;
}
return *ret;
}
BatteryHealth getBatteryHealth(const char* status) {
static SysfsStringEnumMap<BatteryHealth> batteryHealthMap[] = {
{"Unknown", BatteryHealth::UNKNOWN},
{"Good", BatteryHealth::GOOD},
{"Overheat", BatteryHealth::OVERHEAT},
{"Dead", BatteryHealth::DEAD},
{"Over voltage", BatteryHealth::OVER_VOLTAGE},
{"Unspecified failure", BatteryHealth::UNSPECIFIED_FAILURE},
{"Cold", BatteryHealth::COLD},
// battery health values from JEITA spec
{"Warm", BatteryHealth::GOOD},
{"Cool", BatteryHealth::GOOD},
{"Hot", BatteryHealth::OVERHEAT},
{NULL, BatteryHealth::UNKNOWN},
};
auto ret = mapSysfsString(status, batteryHealthMap);
if (!ret) {
KLOG_WARNING(LOG_TAG, "Unknown battery health '%s'\n", status);
*ret = BatteryHealth::UNKNOWN;
}
return *ret;
}
int BatteryMonitor::readFromFile(const String8& path, std::string* buf) {
if (android::base::ReadFileToString(path.c_str(), buf)) {
*buf = android::base::Trim(*buf);
}
return buf->length();
}
BatteryMonitor::PowerSupplyType BatteryMonitor::readPowerSupplyType(const String8& path) {
static SysfsStringEnumMap<int> supplyTypeMap[] = {
{"Unknown", ANDROID_POWER_SUPPLY_TYPE_UNKNOWN},
{"Battery", ANDROID_POWER_SUPPLY_TYPE_BATTERY},
{"UPS", ANDROID_POWER_SUPPLY_TYPE_AC},
{"Mains", ANDROID_POWER_SUPPLY_TYPE_AC},
{"USB", ANDROID_POWER_SUPPLY_TYPE_USB},
{"USB_DCP", ANDROID_POWER_SUPPLY_TYPE_AC},
{"USB_HVDCP", ANDROID_POWER_SUPPLY_TYPE_AC},
{"USB_CDP", ANDROID_POWER_SUPPLY_TYPE_AC},
{"USB_ACA", ANDROID_POWER_SUPPLY_TYPE_AC},
{"USB_C", ANDROID_POWER_SUPPLY_TYPE_AC},
{"USB_PD", ANDROID_POWER_SUPPLY_TYPE_AC},
{"USB_PD_DRP", ANDROID_POWER_SUPPLY_TYPE_USB},
{"Wireless", ANDROID_POWER_SUPPLY_TYPE_WIRELESS},
{NULL, 0},
};
std::string buf;
if (readFromFile(path, &buf) <= 0)
return ANDROID_POWER_SUPPLY_TYPE_UNKNOWN;
auto ret = mapSysfsString(buf.c_str(), supplyTypeMap);
if (!ret) {
KLOG_WARNING(LOG_TAG, "Unknown power supply type '%s'\n", buf.c_str());
*ret = ANDROID_POWER_SUPPLY_TYPE_UNKNOWN;
}
return static_cast<BatteryMonitor::PowerSupplyType>(*ret);
}
bool BatteryMonitor::getBooleanField(const String8& path) {
std::string buf;
bool value = false;
if (readFromFile(path, &buf) > 0)
if (buf[0] != '0')
value = true;
return value;
}
int BatteryMonitor::getIntField(const String8& path) {
std::string buf;
int value = 0;
if (readFromFile(path, &buf) > 0)
android::base::ParseInt(buf, &value);
return value;
}
bool BatteryMonitor::isScopedPowerSupply(const char* name) {
constexpr char kScopeDevice[] = "Device";
String8 path;
path.appendFormat("%s/%s/scope", POWER_SUPPLY_SYSFS_PATH, name);
std::string scope;
return (readFromFile(path, &scope) > 0 && scope == kScopeDevice);
}
void BatteryMonitor::updateValues(void) {
initHealthInfo(mHealthInfo.get());
HealthInfo_1_0& props = mHealthInfo->legacy.legacy;
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);
if (!mHealthdConfig->batteryFullChargePath.isEmpty())
props.batteryFullCharge = getIntField(mHealthdConfig->batteryFullChargePath);
if (!mHealthdConfig->batteryCycleCountPath.isEmpty())
props.batteryCycleCount = getIntField(mHealthdConfig->batteryCycleCountPath);
if (!mHealthdConfig->batteryChargeCounterPath.isEmpty())
props.batteryChargeCounter = getIntField(mHealthdConfig->batteryChargeCounterPath);
if (!mHealthdConfig->batteryCurrentAvgPath.isEmpty())
mHealthInfo->legacy.batteryCurrentAverage =
getIntField(mHealthdConfig->batteryCurrentAvgPath);
if (!mHealthdConfig->batteryChargeTimeToFullNowPath.isEmpty())
mHealthInfo->batteryChargeTimeToFullNowSeconds =
getIntField(mHealthdConfig->batteryChargeTimeToFullNowPath);
if (!mHealthdConfig->batteryFullChargeDesignCapacityUahPath.isEmpty())
mHealthInfo->batteryFullChargeDesignCapacityUah =
getIntField(mHealthdConfig->batteryFullChargeDesignCapacityUahPath);
props.batteryTemperature = mBatteryFixedTemperature ?
mBatteryFixedTemperature :
getIntField(mHealthdConfig->batteryTemperaturePath);
std::string buf;
if (readFromFile(mHealthdConfig->batteryCapacityLevelPath, &buf) > 0)
mHealthInfo->batteryCapacityLevel = getBatteryCapacityLevel(buf.c_str());
if (readFromFile(mHealthdConfig->batteryStatusPath, &buf) > 0)
props.batteryStatus = getBatteryStatus(buf.c_str());
if (readFromFile(mHealthdConfig->batteryHealthPath, &buf) > 0)
props.batteryHealth = getBatteryHealth(buf.c_str());
if (readFromFile(mHealthdConfig->batteryTechnologyPath, &buf) > 0)
props.batteryTechnology = String8(buf.c_str());
double MaxPower = 0;
for (size_t i = 0; i < mChargerNames.size(); i++) {
String8 path;
path.appendFormat("%s/%s/online", POWER_SUPPLY_SYSFS_PATH,
mChargerNames[i].string());
if (getIntField(path)) {
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());
int ChargingCurrent =
(access(path.string(), R_OK) == 0) ? getIntField(path) : 0;
path.clear();
path.appendFormat("%s/%s/voltage_max", POWER_SUPPLY_SYSFS_PATH,
mChargerNames[i].string());
int ChargingVoltage =
(access(path.string(), R_OK) == 0) ? getIntField(path) :
DEFAULT_VBUS_VOLTAGE;
double power = ((double)ChargingCurrent / MILLION) *
((double)ChargingVoltage / MILLION);
if (MaxPower < power) {
props.maxChargingCurrent = ChargingCurrent;
props.maxChargingVoltage = ChargingVoltage;
MaxPower = power;
}
}
}
}
void BatteryMonitor::logValues(void) {
char dmesgline[256];
size_t len;
const HealthInfo_1_0& props = mHealthInfo->legacy.legacy;
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 {
len = snprintf(dmesgline, sizeof(dmesgline), "battery none");
}
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);
}
bool BatteryMonitor::isChargerOnline() {
const HealthInfo_1_0& props = mHealthInfo->legacy.legacy;
return props.chargerAcOnline | props.chargerUsbOnline |
props.chargerWirelessOnline;
}
int BatteryMonitor::getChargeStatus() {
BatteryStatus result = BatteryStatus::UNKNOWN;
if (!mHealthdConfig->batteryStatusPath.isEmpty()) {
std::string buf;
if (readFromFile(mHealthdConfig->batteryStatusPath, &buf) > 0)
result = getBatteryStatus(buf.c_str());
}
return static_cast<int>(result);
}
status_t BatteryMonitor::getProperty(int id, struct BatteryProperty *val) {
status_t ret = BAD_VALUE;
std::string buf;
val->valueInt64 = LONG_MIN;
switch(id) {
case BATTERY_PROP_CHARGE_COUNTER:
if (!mHealthdConfig->batteryChargeCounterPath.isEmpty()) {
val->valueInt64 =
getIntField(mHealthdConfig->batteryChargeCounterPath);
ret = OK;
} else {
ret = NAME_NOT_FOUND;
}
break;
case BATTERY_PROP_CURRENT_NOW:
if (!mHealthdConfig->batteryCurrentNowPath.isEmpty()) {
val->valueInt64 =
getIntField(mHealthdConfig->batteryCurrentNowPath);
ret = OK;
} else {
ret = NAME_NOT_FOUND;
}
break;
case BATTERY_PROP_CURRENT_AVG:
if (!mHealthdConfig->batteryCurrentAvgPath.isEmpty()) {
val->valueInt64 =
getIntField(mHealthdConfig->batteryCurrentAvgPath);
ret = OK;
} else {
ret = NAME_NOT_FOUND;
}
break;
case BATTERY_PROP_CAPACITY:
if (!mHealthdConfig->batteryCapacityPath.isEmpty()) {
val->valueInt64 =
getIntField(mHealthdConfig->batteryCapacityPath);
ret = OK;
} 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;
case BATTERY_PROP_BATTERY_STATUS:
val->valueInt64 = getChargeStatus();
ret = OK;
break;
default:
break;
}
return ret;
}
void BatteryMonitor::dumpState(int fd) {
int v;
char vs[128];
const HealthInfo_1_0& props = mHealthInfo->legacy.legacy;
snprintf(vs, sizeof(vs), "ac: %d usb: %d wireless: %d current_max: %d voltage_max: %d\n",
props.chargerAcOnline, props.chargerUsbOnline,
props.chargerWirelessOnline, props.maxChargingCurrent,
props.maxChargingVoltage);
write(fd, vs, strlen(vs));
snprintf(vs, sizeof(vs), "status: %d health: %d present: %d\n",
props.batteryStatus, props.batteryHealth, props.batteryPresent);
write(fd, vs, strlen(vs));
snprintf(vs, sizeof(vs), "level: %d voltage: %d temp: %d\n",
props.batteryLevel, props.batteryVoltage,
props.batteryTemperature);
write(fd, vs, strlen(vs));
if (!mHealthdConfig->batteryCurrentNowPath.isEmpty()) {
v = getIntField(mHealthdConfig->batteryCurrentNowPath);
snprintf(vs, sizeof(vs), "current now: %d\n", v);
write(fd, vs, strlen(vs));
}
if (!mHealthdConfig->batteryCurrentAvgPath.isEmpty()) {
v = getIntField(mHealthdConfig->batteryCurrentAvgPath);
snprintf(vs, sizeof(vs), "current avg: %d\n", v);
write(fd, vs, strlen(vs));
}
if (!mHealthdConfig->batteryChargeCounterPath.isEmpty()) {
v = getIntField(mHealthdConfig->batteryChargeCounterPath);
snprintf(vs, sizeof(vs), "charge counter: %d\n", v);
write(fd, vs, strlen(vs));
}
if (!mHealthdConfig->batteryCurrentNowPath.isEmpty()) {
snprintf(vs, sizeof(vs), "current now: %d\n", props.batteryCurrent);
write(fd, vs, strlen(vs));
}
if (!mHealthdConfig->batteryCycleCountPath.isEmpty()) {
snprintf(vs, sizeof(vs), "cycle count: %d\n", props.batteryCycleCount);
write(fd, vs, strlen(vs));
}
if (!mHealthdConfig->batteryFullChargePath.isEmpty()) {
snprintf(vs, sizeof(vs), "Full charge: %d\n", props.batteryFullCharge);
write(fd, vs, strlen(vs));
}
}
void BatteryMonitor::init(struct healthd_config *hc) {
String8 path;
char pval[PROPERTY_VALUE_MAX];
mHealthdConfig = hc;
std::unique_ptr<DIR, decltype(&closedir)> dir(opendir(POWER_SUPPLY_SYSFS_PATH), closedir);
if (dir == NULL) {
KLOG_ERROR(LOG_TAG, "Could not open %s\n", POWER_SUPPLY_SYSFS_PATH);
} else {
struct dirent* entry;
while ((entry = readdir(dir.get()))) {
const char* name = entry->d_name;
std::vector<String8>::iterator itIgnoreName;
if (!strcmp(name, ".") || !strcmp(name, ".."))
continue;
itIgnoreName = find(hc->ignorePowerSupplyNames.begin(),
hc->ignorePowerSupplyNames.end(), String8(name));
if (itIgnoreName != hc->ignorePowerSupplyNames.end())
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_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:
// Some devices expose the battery status of sub-component like
// stylus. Such a device-scoped battery info needs to be skipped
// in BatteryMonitor, which is intended to report the status of
// the battery supplying the power to the whole system.
if (isScopedPowerSupply(name)) continue;
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;
}
}
if (mHealthdConfig->batteryFullChargePath.isEmpty()) {
path.clear();
path.appendFormat("%s/%s/charge_full",
POWER_SUPPLY_SYSFS_PATH, name);
if (access(path, R_OK) == 0)
mHealthdConfig->batteryFullChargePath = 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->batteryCycleCountPath.isEmpty()) {
path.clear();
path.appendFormat("%s/%s/cycle_count",
POWER_SUPPLY_SYSFS_PATH, name);
if (access(path, R_OK) == 0)
mHealthdConfig->batteryCycleCountPath = path;
}
if (mHealthdConfig->batteryCapacityLevelPath.isEmpty()) {
path.clear();
path.appendFormat("%s/%s/capacity_level", POWER_SUPPLY_SYSFS_PATH, name);
if (access(path, R_OK) == 0) mHealthdConfig->batteryCapacityLevelPath = path;
}
if (mHealthdConfig->batteryChargeTimeToFullNowPath.isEmpty()) {
path.clear();
path.appendFormat("%s/%s/time_to_full_now", POWER_SUPPLY_SYSFS_PATH, name);
if (access(path, R_OK) == 0)
mHealthdConfig->batteryChargeTimeToFullNowPath = path;
}
if (mHealthdConfig->batteryFullChargeDesignCapacityUahPath.isEmpty()) {
path.clear();
path.appendFormat("%s/%s/charge_full_design", POWER_SUPPLY_SYSFS_PATH, name);
if (access(path, R_OK) == 0)
mHealthdConfig->batteryFullChargeDesignCapacityUahPath = 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;
}
}
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;
}
}
}
// Typically the case for devices which do not have a battery and
// and are always plugged into AC mains.
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 (mHealthdConfig->batteryCurrentNowPath.isEmpty())
KLOG_WARNING(LOG_TAG, "BatteryCurrentNowPath not found\n");
if (mHealthdConfig->batteryFullChargePath.isEmpty())
KLOG_WARNING(LOG_TAG, "BatteryFullChargePath not found\n");
if (mHealthdConfig->batteryCycleCountPath.isEmpty())
KLOG_WARNING(LOG_TAG, "BatteryCycleCountPath not found\n");
if (mHealthdConfig->batteryCapacityLevelPath.isEmpty())
KLOG_WARNING(LOG_TAG, "batteryCapacityLevelPath not found\n");
if (mHealthdConfig->batteryChargeTimeToFullNowPath.isEmpty())
KLOG_WARNING(LOG_TAG, "batteryChargeTimeToFullNowPath. not found\n");
if (mHealthdConfig->batteryFullChargeDesignCapacityUahPath.isEmpty())
KLOG_WARNING(LOG_TAG, "batteryFullChargeDesignCapacityUahPath. 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;
}
}
}; // namespace android