#include "battery.h"
#include "common/io/io.h"
#include "util/FFstrbuf.h"
#include "util/stringUtils.h"
#include <prop/prop_array.h>
#include <prop/prop_bool.h>
#include <prop/prop_dictionary.h>
#include <prop/prop_object.h>
#include <sys/envsys.h>
#include <prop/proplib.h>
#include <paths.h>
#include <time.h>
#include <unistd.h>
#include <fcntl.h>
const char* ffDetectBattery(FF_MAYBE_UNUSED FFBatteryOptions* options, FFlist* results)
{
FF_AUTO_CLOSE_FD int fd = open(_PATH_SYSMON, O_RDONLY);
if (fd < 0) return "open(_PATH_SYSMON, O_RDONLY) failed";
prop_dictionary_t root = NULL;
if (prop_dictionary_recv_ioctl(fd, ENVSYS_GETDICTIONARY, &root) < 0)
return "prop_dictionary_recv_ioctl(ENVSYS_GETDICTIONARY) failed";
bool acConnected = false;
{
prop_array_t acad = prop_dictionary_get(root, "acpiacad0");
if (acad)
{
prop_dictionary_t dict = prop_array_get(acad, 0);
prop_dictionary_get_uint8(dict, "cur-value", (uint8_t*) &acConnected);
}
}
prop_object_iterator_t itKey = prop_dictionary_iterator(root);
for (prop_dictionary_keysym_t key; (key = prop_object_iterator_next(itKey)) != NULL; )
{
if (!ffStrStartsWith(prop_dictionary_keysym_value(key), "acpibat")) continue;
prop_array_t bat = prop_dictionary_get_keysym(root, key);
uint32_t max = 0, curr = 0, dischargeRate = 0;
bool charging = false, critical = false;
prop_object_iterator_t iter = prop_array_iterator(bat);
for (prop_dictionary_t dict; (dict = prop_object_iterator_next(iter)) != NULL;)
{
if (prop_object_type(dict) != PROP_TYPE_DICTIONARY)
continue;
const char* desc = NULL;
if (!prop_dictionary_get_string(dict, "description", &desc))
continue;
if (ffStrEquals(desc, "present"))
{
int value = 0;
if (prop_dictionary_get_int(dict, "cur-value", &value) && value == 0)
continue;
}
else if (ffStrEquals(desc, "charging"))
{
prop_dictionary_get_uint8(dict, "cur-value", (uint8_t*) &charging);
}
else if (ffStrEquals(desc, "charge"))
{
prop_dictionary_get_uint32(dict, "max-value", &max);
prop_dictionary_get_uint32(dict, "cur-value", &curr);
const char* state = NULL;
if (prop_dictionary_get_string(dict, "state", &state) && ffStrEquals(state, "critical"))
critical = true;
}
else if (ffStrEquals(desc, "discharge rate"))
prop_dictionary_get_uint(dict, "cur-value", &dischargeRate);
}
if (max > 0)
{
FFBatteryResult* battery = ffListAdd(results);
battery->temperature = FF_BATTERY_TEMP_UNSET;
battery->cycleCount = 0;
ffStrbufInit(&battery->manufacturer);
ffStrbufInit(&battery->modelName);
ffStrbufInit(&battery->status);
ffStrbufInit(&battery->technology);
ffStrbufInit(&battery->serial);
ffStrbufInit(&battery->manufactureDate);
battery->timeRemaining = -1;
battery->capacity = (double) curr / (double) max * 100.;
if (charging)
ffStrbufAppendS(&battery->status, "Charging, ");
else if (dischargeRate)
{
ffStrbufAppendS(&battery->status, "Discharging, ");
battery->timeRemaining = (int32_t)((double)curr / dischargeRate * 3600);
}
if (critical)
ffStrbufAppendS(&battery->status, "Critical, ");
if (acConnected)
ffStrbufAppendS(&battery->status, "AC Connected");
ffStrbufTrimRight(&battery->status, ' ');
ffStrbufTrimRight(&battery->status, ',');
}
prop_object_iterator_release(iter);
}
prop_object_iterator_release(itKey);
prop_object_release(root);
return NULL;
}