#endif
struct battery_info {
+ int full_design;
+ int full_last;
+ int remaining;
+
int present_rate;
int seconds_remaining;
float percentage_remaining;
char buf[1024];
const char *walk, *last;
bool watt_as_unit = false;
- int full_design = -1,
- remaining = -1,
- voltage = -1;
+ int voltage = -1;
char batpath[512];
sprintf(batpath, path, number);
INSTANCE(batpath);
if (BEGINS_WITH(last, "POWER_SUPPLY_ENERGY_NOW")) {
watt_as_unit = true;
- remaining = atoi(walk + 1);
+ batt_info->remaining = atoi(walk + 1);
} else if (BEGINS_WITH(last, "POWER_SUPPLY_CHARGE_NOW")) {
watt_as_unit = false;
- remaining = atoi(walk + 1);
+ batt_info->remaining = atoi(walk + 1);
} else if (BEGINS_WITH(last, "POWER_SUPPLY_CURRENT_NOW"))
batt_info->present_rate = abs(atoi(walk + 1));
else if (BEGINS_WITH(last, "POWER_SUPPLY_VOLTAGE_NOW"))
batt_info->status = CS_DISCHARGING;
else if (BEGINS_WITH(last, "POWER_SUPPLY_STATUS="))
batt_info->status = CS_UNKNOWN;
- else {
- /* The only thing left is the full capacity */
- if (last_full_capacity) {
- if (!BEGINS_WITH(last, "POWER_SUPPLY_ENERGY_FULL") &&
- !BEGINS_WITH(last, "POWER_SUPPLY_CHARGE_FULL"))
- continue;
- } else {
- if (!BEGINS_WITH(last, "POWER_SUPPLY_CHARGE_FULL_DESIGN") &&
- !BEGINS_WITH(last, "POWER_SUPPLY_ENERGY_FULL_DESIGN"))
- continue;
- }
-
- full_design = atoi(walk + 1);
- }
+ else if (BEGINS_WITH(last, "POWER_SUPPLY_CHARGE_FULL_DESIGN") ||
+ BEGINS_WITH(last, "POWER_SUPPLY_ENERGY_FULL_DESIGN"))
+ batt_info->full_design = atoi(walk + 1);
+ else if (BEGINS_WITH(last, "POWER_SUPPLY_ENERGY_FULL") ||
+ BEGINS_WITH(last, "POWER_SUPPLY_CHARGE_FULL"))
+ batt_info->full_last = atoi(walk + 1);
}
/* the difference between POWER_SUPPLY_ENERGY_NOW and
* POWER_SUPPLY_CHARGE_NOW is the unit of measurement. The energy is
* given in mWh, the charge in mAh. So calculate every value given in
* ampere to watt */
- if (!watt_as_unit) {
+ if (!watt_as_unit && voltage != -1) {
batt_info->present_rate = (((float)voltage / 1000.0) * ((float)batt_info->present_rate / 1000.0));
-
- if (voltage != -1) {
- remaining = (((float)voltage / 1000.0) * ((float)remaining / 1000.0));
- full_design = (((float)voltage / 1000.0) * ((float)full_design / 1000.0));
- }
+ batt_info->remaining = (((float)voltage / 1000.0) * ((float)batt_info->remaining / 1000.0));
+ batt_info->full_design = (((float)voltage / 1000.0) * ((float)batt_info->full_design / 1000.0));
}
- if ((full_design == -1) || (remaining == -1)) {
+ int full = (last_full_capacity ? batt_info->full_last : batt_info->full_design);
+
+ if ((full == -1) || (batt_info->remaining == -1)) {
OUTPUT_FULL_TEXT(format_down);
return false;
}
- batt_info->percentage_remaining = (((float)remaining / (float)full_design) * 100);
+ batt_info->percentage_remaining = (((float)batt_info->remaining / (float)full) * 100);
/* Some batteries report POWER_SUPPLY_CHARGE_NOW=<full_design> when fully
* charged, even though that’s plainly wrong. For people who chose to see
* the percentage calculated based on the last full capacity, we clamp the
}
if (batt_info->present_rate > 0 && batt_info->status != CS_FULL) {
- batt_info->seconds_remaining = seconds_remaining_from_rate(batt_info->status, full_design, remaining, batt_info->present_rate);
+ batt_info->seconds_remaining = seconds_remaining_from_rate(batt_info->status, full, batt_info->remaining, batt_info->present_rate);
}
#elif defined(__FreeBSD__) || defined(__FreeBSD_kernel__) || defined(__DragonFly__)
int state;
* Using envsys(4) via sysmon(4).
*/
bool watt_as_unit = false;
- int full_design = -1,
- remaining = -1,
- voltage = -1;
- int fd, rval, last_full_cap;
+ int voltage = -1;
+ int fd, rval;
bool is_found = false;
char *sensor_desc;
bool is_full = false;
obj4 = prop_dictionary_get(obj2, "max-value");
obj5 = prop_dictionary_get(obj2, "type");
- remaining = prop_number_integer_value(obj3);
- full_design = prop_number_integer_value(obj4);
+ batt_info->remaining = prop_number_integer_value(obj3);
+ batt_info->full_design = prop_number_integer_value(obj4);
- if (remaining == full_design)
+ if (batt_info->remaining == batt_info->full_design)
is_full = true;
if (strcmp("Ampere hour", prop_string_cstring_nocopy(obj5)) == 0)
batt_info->present_rate = prop_number_integer_value(obj3);
} else if (strcmp("last full cap", prop_string_cstring_nocopy(obj3)) == 0) {
obj3 = prop_dictionary_get(obj2, "cur-value");
- last_full_cap = prop_number_integer_value(obj3);
+ batt_info->full_last = prop_number_integer_value(obj3);
} else if (strcmp("voltage", prop_string_cstring_nocopy(obj3)) == 0) {
obj3 = prop_dictionary_get(obj2, "cur-value");
voltage = prop_number_integer_value(obj3);
return false;
}
- if (last_full_capacity)
- full_design = last_full_cap;
-
- if (!watt_as_unit) {
+ if (!watt_as_unit && voltage != -1) {
batt_info->present_rate = (((float)voltage / 1000.0) * ((float)batt_info->present_rate / 1000.0));
- remaining = (((float)voltage / 1000.0) * ((float)remaining / 1000.0));
- full_design = (((float)voltage / 1000.0) * ((float)full_design / 1000.0));
+ batt_info->remaining = (((float)voltage / 1000.0) * ((float)batt_info->remaining / 1000.0));
+ batt_info->full_design = (((float)voltage / 1000.0) * ((float)batt_info->full_design / 1000.0));
}
+ int full = (last_full_capacity ? batt_info->full_last : batt_info->full_design);
+
batt_info->percentage_remaining =
- (((float)remaining / (float)full_design) * 100);
+ (((float)batt_info->remaining / (float)full) * 100);
if (is_full)
batt_info->status = CS_FULL;
* The envsys(4) ACPI routines do not appear to provide a 'time
* remaining' figure, so we must deduce it.
*/
- batt_info->seconds_remaining = seconds_remaining_from_rate(batt_info->status, full_design, remaining, batt_info->present_rate);
+ batt_info->seconds_remaining = seconds_remaining_from_rate(batt_info->status, full, batt_info->remaining, batt_info->present_rate);
#endif
return true;
projects / i3 / i3status / commitdiff