enlightenment/src/modules/battery/e_mod_sysctl.c

#include <err.h>
#include <sys/types.h>
#include <sys/sysctl.h>

#if defined(__OpenBSD__) || defined(__NetBSD__)
#include <sys/param.h>
#include <sys/sensors.h>
#endif

#include "e.h"
#include "e_mod_main.h"

static Eina_Bool _battery_sysctl_battery_update_poll(void *data EINA_UNUSED);
static int       _battery_sysctl_battery_update();

extern Eina_List *device_batteries;
extern Eina_List *device_ac_adapters;
extern double init_time;

static Ac_Adapter *ac = NULL;
static Battery *bat = NULL;

int
_battery_sysctl_start(void)
{
#if defined(__OpenBSD__) || defined(__NetBSD__)
   int mib[] = {CTL_HW, HW_SENSORS, 0, 0, 0};
   int devn;
   struct sensordev snsrdev;
   size_t sdlen = sizeof(struct sensordev);
#elif defined(__FreeBSD__) || defined(__DragonFly__)
   int result;
   size_t len;
#endif

#if defined(__OpenBSD__) || defined(__NetBSD__)
   for (devn = 0;; devn++) {
        mib[2] = devn;
        if (sysctl(mib, 3, &snsrdev, &sdlen, NULL, 0) == -1)
          {
             if (errno == ENXIO)
               continue;
             if (errno == ENOENT)
               break;
          }

        if (!strcmp("acpibat0", snsrdev.xname))
          {
             if (!(bat = E_NEW(Battery, 1)))
               return 0;
             bat->udi = eina_stringshare_add("acpibat0"),
             bat->mib = malloc(sizeof(int) * 5);
             if (!bat->mib) return 0;
             bat->mib[0] = mib[0];
             bat->mib[1] = mib[1];
             bat->mib[2] = mib[2];
             bat->technology = eina_stringshare_add("Unknown");
             bat->model = eina_stringshare_add("Unknown");
             bat->vendor = eina_stringshare_add("Unknown");
             bat->poll = ecore_poller_add(ECORE_POLLER_CORE,
                                          battery_config->poll_interval,
                                          _battery_sysctl_battery_update_poll, NULL);
             device_batteries = eina_list_append(device_batteries, bat);
          }
        else if (!strcmp("acpiac0", snsrdev.xname))
          {
             if (!(ac = E_NEW(Ac_Adapter, 1)))
               return 0;
             ac->udi = eina_stringshare_add("acpiac0");
             ac->mib = malloc(sizeof(int) * 5);
             if (!ac->mib) return 0;
             ac->mib[0] = mib[0];
             ac->mib[1] = mib[1];
             ac->mib[2] = mib[2];
             device_ac_adapters = eina_list_append(device_ac_adapters, ac);
          }
     }
#elif defined(__FreeBSD__) || defined(__DragonFly__)
     if ((sysctlbyname("hw.acpi.battery.life", NULL, &len, NULL, 0)) != -1)
       {
          if (!(bat = E_NEW(Battery, 1)))
            return 0;
          
          bat->mib = malloc(sizeof(int) * 4);
          if (!bat->mib) return 0;
          sysctlnametomib("hw.acpi.battery.life", bat->mib, &len); 

          bat->mib_state = malloc(sizeof(int) * 4);
          if (!bat->mib_state) return 0;
          sysctlnametomib("hw.acpi.battery.state", bat->mib_state, &len);

          bat->mib_time  = malloc(sizeof(int) * 4);
          if (!bat->mib_time) return 0;
          sysctlnametomib("hw.acpi.battery.time", bat->mib_time, &len);

          bat->mib_units = malloc(sizeof(int) * 4);
          if(!bat->mib_units) return 0;
          sysctlnametomib("hw.acpi.battery.units", bat->mib_units, &len);

          bat->udi = eina_stringshare_add("hw.acpi.battery");
          bat->technology = eina_stringshare_add("Unknown");
          bat->model = eina_stringshare_add("Unknown");
          bat->vendor = eina_stringshare_add("Unknown");

          bat->poll = ecore_poller_add(ECORE_POLLER_CORE,
		                       battery_config->poll_interval,
                                       _battery_sysctl_battery_update_poll, NULL);

          device_batteries = eina_list_append(device_batteries, bat);
      }

      if ((sysctlbyname("hw.acpi.acline", NULL, &len, NULL, 0)) != -1)
        {
           if (!(ac = E_NEW(Ac_Adapter, 1)))
             return 0;

           ac->mib = malloc(sizeof(int) * 3);
           if (!ac->mib) return 0;
           len = sizeof(ac->mib);
           sysctlnametomib("hw.acpi.acline", ac->mib, &len);

           ac->udi = eina_stringshare_add("hw.acpi.acline");

           device_ac_adapters = eina_list_append(device_ac_adapters, ac);
        }
#endif
   _battery_sysctl_battery_update();

   bat->last_update = ecore_time_get();

   return 1;
}

void
_battery_sysctl_stop(void)
{
   if (ac)
     {
        eina_stringshare_del(ac->udi);
        E_FREE(ac->mib);
        E_FREE(ac);
     }

   if (bat)
     {
        eina_stringshare_del(bat->udi);
        eina_stringshare_del(bat->technology);
        eina_stringshare_del(bat->model);
        eina_stringshare_del(bat->vendor);
        ecore_poller_del(bat->poll);
#if defined(__FreeBSD__) || defined(__DragonFly__)
        E_FREE(bat->mib_state);
        E_FREE(bat->mib_time);
        E_FREE(bat->mib_units);
#endif
        E_FREE(bat->mib);
        E_FREE(bat);
     }
}

static Eina_Bool
_battery_sysctl_battery_update_poll(void *data EINA_UNUSED)
{
   _battery_sysctl_battery_update();
   return EINA_TRUE;
}

static int
_battery_sysctl_battery_update()
{
   double _time, charge;
#if defined(__OpenBSD__) || defined(__NetBSD__)
   struct sensor s;
   size_t slen = sizeof(struct sensor);
#elif defined(__FreeBSD__) || defined(__DragonFly__)
   int value;
   size_t len;
#endif

   if (bat)
     {
       /* update the poller interval */
       ecore_poller_poller_interval_set(bat->poll,
                                        battery_config->poll_interval);
#if defined(__OpenBSD__) || defined(__NetBSD__)
       /* last full capacity */
       bat->mib[3] = 7;
       bat->mib[4] = 0;
       if (sysctl(bat->mib, 5, &s, &slen, NULL, 0) != -1)
         {
            bat->last_full_charge = (double)s.value;
         }
    
       /* remaining capacity */
       bat->mib[3] = 7;
       bat->mib[4] = 3;
       if (sysctl(bat->mib, 5, &s, &slen, NULL, 0) != -1)
         {
            charge = (double)s.value;
         }
  
       /* This is a workaround because there's an ACPI bug */ 
       if ((EINA_FLT_EQ(charge, 0.0)) || (EINA_FLT_EQ(bat->last_full_charge, 0.0)))
         {
           /* last full capacity */
           bat->mib[3] = 8;
           bat->mib[4] = 0;
           if (sysctl(bat->mib, 5, &s, &slen, NULL, 0) != -1)
             {
                bat->last_full_charge = (double)s.value;
             }

           /* remaining capacity */
           bat->mib[3] = 8;
           bat->mib[4] = 3;
           if (sysctl(bat->mib, 5, &s, &slen, NULL, 0) != -1)
             {
                charge = (double)s.value;
             }
         }

       bat->got_prop = 1;
 
       _time = ecore_time_get();
       if ((bat->got_prop) && (!EINA_FLT_EQ(charge, bat->current_charge)))
         bat->charge_rate = ((charge - bat->current_charge) / (_time - bat->last_update));
       bat->last_update = _time;
       bat->current_charge = charge;
       bat->percent = 100 * (bat->current_charge / bat->last_full_charge);
       if (bat->current_charge >= bat->last_full_charge)
         bat->percent = 100;

       if (bat->got_prop)
         {
            if (bat->charge_rate > 0)
              {
                 if (battery_config->fuzzy && (++battery_config->fuzzcount <= 10) && (bat->time_full > 0))
                   bat->time_full = (((bat->last_full_charge - bat->current_charge) / bat->charge_rate) + bat->time_full) / 2;
                 else
                   bat->time_full = (bat->last_full_charge - bat->current_charge) / bat->charge_rate;
                 bat->time_left = -1;
              }
            else
              {
                 if (battery_config->fuzzy && (battery_config->fuzzcount <= 10) && (bat->time_left > 0))
                   bat->time_left = (((0 - bat->current_charge) / bat->charge_rate) + bat->time_left) / 2;
                 else
                   bat->time_left = (0 - bat->current_charge) / bat->charge_rate;
                 bat->time_full = -1;
              }
         }
       else
         {
            bat->time_full = -1;
            bat->time_left = -1;
         }
    
       /* battery state 1: discharge, 2: charge */
       bat->mib[3] = 10;
       bat->mib[4] = 0;
       if (sysctl(bat->mib, 5, &s, &slen, NULL, 0) == -1)
         {
            if (s.value == 2)
              bat->charging = 1;
            else
              bat->charging = 0;
         }

#elif defined(__FreeBSD__) || defined(__DragonFly__)
       len = sizeof(value);
       if ((sysctl(bat->mib, 4, &value, &len, NULL, 0)) == -1)
         {
           return 0;
         }
    
       bat->percent = value;

       _time = ecore_time_get();
       bat->last_update = _time;

       len = sizeof(value);
       if ((sysctl(bat->mib_state, 4, &value, &len, NULL, 0)) == -1)
         {
           return 0;
         }

       bat->charging = !value;
       bat->got_prop = 1;

       bat->time_full = -1;
       bat->time_left = -1;

       len = sizeof(bat->time_min);
       if ((sysctl(bat->mib_time, 4, &bat->time_min, &len, NULL, 0)) == -1)
         {
            bat->time_min = -1;
         }

       len = sizeof(bat->batteries);
       if ((sysctl(bat->mib_units, 4, &bat->batteries, &len, NULL, 0)) == -1)
         {
            bat->batteries = 1;
         }

       if (bat->time_min >= 0) bat->time_left = bat->time_min * 60;
       if (bat->batteries == 1) bat->time_left = -1;
#endif 
   } 

   if (ac)
     {
#if defined(__OpenBSD__) || defined(__NetBSD__)
       /* AC State */
       ac->mib[3] = 9;
       ac->mib[4] = 0;
       if (sysctl(ac->mib, 5, &s, &slen, NULL, 0) != -1)
         {
            if (s.value)
              ac->present = 1;
            else
              ac->present = 0;
         }
#elif defined(__FreeBSD__) || defined(__DragonFly__)
       len = sizeof(value);
       if ((sysctl(ac->mib, 3, &value, &len, NULL, 0)) != -1)
         {
            ac->present = value;
         }
#endif
     } 

   if (bat)
     {
        if (bat->got_prop)
          _battery_device_update();
        bat->got_prop = 1;
     }
   return 1;  
}