// vim:ts=4:sw=4:expandtab
#include <ctype.h>
-#include <time.h>
-#include <string.h>
-#include <stdlib.h>
#include <stdio.h>
+#include <stdlib.h>
+#include <string.h>
+#include <time.h>
#include <yajl/yajl_gen.h>
#include <yajl/yajl_version.h>
#include "i3status.h"
-#if defined(__FreeBSD__) || defined(__FreeBSD_kernel__) || defined(__DragonFly__)
+#if defined(LINUX)
+#include <errno.h>
+#include <glob.h>
#include <sys/types.h>
-#include <sys/sysctl.h>
-#include <dev/acpica/acpiio.h>
#endif
-#if defined(__OpenBSD__)
+#if defined(__FreeBSD__) || defined(__FreeBSD_kernel__) || defined(__DragonFly__)
+#include <dev/acpica/acpiio.h>
+#include <sys/sysctl.h>
#include <sys/types.h>
-#include <sys/ioctl.h>
+#endif
+
+#if defined(__DragonFly__)
#include <sys/fcntl.h>
+#endif
+
+#if defined(__OpenBSD__)
#include <machine/apmvar.h>
+#include <sys/fcntl.h>
+#include <sys/ioctl.h>
+#include <sys/types.h>
#endif
#if defined(__NetBSD__)
#include <sys/envsys.h>
#endif
+typedef enum {
+ CS_UNKNOWN,
+ CS_DISCHARGING,
+ CS_CHARGING,
+ CS_FULL,
+} charging_status_t;
+
+/* A description of the state of one or more batteries. */
struct battery_info {
- int full_design;
- int full_last;
- int remaining;
+ /* measured properties */
+ int full_design; /* in uAh */
+ int full_last; /* in uAh */
+ int remaining; /* in uAh */
+ int present_rate; /* in uA, always non-negative */
- int present_rate;
+ /* derived properties */
int seconds_remaining;
float percentage_remaining;
charging_status_t status;
};
+#if defined(__DragonFly__)
+#define ACPIDEV "/dev/acpi"
+static int acpifd;
+
+static bool acpi_init(void) {
+ if (acpifd == 0) {
+ acpifd = open(ACPIDEV, O_RDWR);
+ if (acpifd == -1)
+ acpifd = open(ACPIDEV, O_RDONLY);
+ if (acpifd == -1)
+ return false;
+ }
+ return true;
+}
+#endif
+
+#if defined(LINUX) || defined(__NetBSD__)
+/*
+ * Add batt_info data to acc.
+ */
+static void add_battery_info(struct battery_info *acc, const struct battery_info *batt_info) {
+ if (acc->remaining < 0) {
+ /* initialize accumulator so we can add to it */
+ acc->full_design = 0;
+ acc->full_last = 0;
+ acc->remaining = 0;
+ acc->present_rate = 0;
+ }
+
+ acc->full_design += batt_info->full_design;
+ acc->full_last += batt_info->full_last;
+ acc->remaining += batt_info->remaining;
+
+ /* make present_rate negative for discharging and positive for charging */
+ int present_rate = (acc->status == CS_DISCHARGING ? -1 : 1) * acc->present_rate;
+ present_rate += (batt_info->status == CS_DISCHARGING ? -1 : 1) * batt_info->present_rate;
+
+ /* merge status */
+ switch (acc->status) {
+ case CS_UNKNOWN:
+ acc->status = batt_info->status;
+ break;
+
+ case CS_DISCHARGING:
+ if (present_rate > 0)
+ acc->status = CS_CHARGING;
+ /* else if batt_info is DISCHARGING: no conflict
+ * else if batt_info is CHARGING: present_rate should indicate that
+ * else if batt_info is FULL: but something else is discharging */
+ break;
+
+ case CS_CHARGING:
+ if (present_rate < 0)
+ acc->status = CS_DISCHARGING;
+ /* else if batt_info is DISCHARGING: present_rate should indicate that
+ * else if batt_info is CHARGING: no conflict
+ * else if batt_info is FULL: but something else is charging */
+ break;
+
+ case CS_FULL:
+ if (batt_info->status != CS_UNKNOWN)
+ acc->status = batt_info->status;
+ /* else: retain FULL, since it is more specific than UNKNOWN */
+ break;
+ }
+
+ acc->present_rate = abs(present_rate);
+}
+#endif
+
static bool slurp_battery_info(struct battery_info *batt_info, yajl_gen json_gen, char *buffer, int number, const char *path, const char *format_down) {
char *outwalk = buffer;
if (*walk != '=')
continue;
- if (BEGINS_WITH(last, "POWER_SUPPLY_ENERGY_NOW")) {
+ if (BEGINS_WITH(last, "POWER_SUPPLY_ENERGY_NOW=")) {
watt_as_unit = true;
batt_info->remaining = atoi(walk + 1);
- } else if (BEGINS_WITH(last, "POWER_SUPPLY_CHARGE_NOW")) {
+ batt_info->percentage_remaining = -1;
+ } else if (BEGINS_WITH(last, "POWER_SUPPLY_CHARGE_NOW=")) {
watt_as_unit = false;
batt_info->remaining = atoi(walk + 1);
- } else if (BEGINS_WITH(last, "POWER_SUPPLY_CURRENT_NOW"))
+ batt_info->percentage_remaining = -1;
+ } else if (BEGINS_WITH(last, "POWER_SUPPLY_CAPACITY=") && batt_info->remaining == -1) {
+ batt_info->percentage_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"))
+ else if (BEGINS_WITH(last, "POWER_SUPPLY_VOLTAGE_NOW="))
voltage = abs(atoi(walk + 1));
/* on some systems POWER_SUPPLY_POWER_NOW does not exist, but actually
* it is the same as POWER_SUPPLY_CURRENT_NOW but with μWh as
* unit instead of μAh. We will calculate it as we need it
* later. */
- else if (BEGINS_WITH(last, "POWER_SUPPLY_POWER_NOW"))
+ else if (BEGINS_WITH(last, "POWER_SUPPLY_POWER_NOW="))
batt_info->present_rate = abs(atoi(walk + 1));
else if (BEGINS_WITH(last, "POWER_SUPPLY_STATUS=Charging"))
batt_info->status = CS_CHARGING;
else if (BEGINS_WITH(last, "POWER_SUPPLY_STATUS=Full"))
batt_info->status = CS_FULL;
- else if (BEGINS_WITH(last, "POWER_SUPPLY_STATUS=Discharging"))
+ else if (BEGINS_WITH(last, "POWER_SUPPLY_STATUS=Discharging") || BEGINS_WITH(last, "POWER_SUPPLY_STATUS=Not charging"))
batt_info->status = CS_DISCHARGING;
else if (BEGINS_WITH(last, "POWER_SUPPLY_STATUS="))
batt_info->status = CS_UNKNOWN;
- else if (BEGINS_WITH(last, "POWER_SUPPLY_CHARGE_FULL_DESIGN") ||
- BEGINS_WITH(last, "POWER_SUPPLY_ENERGY_FULL_DESIGN"))
+ 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"))
+ else if (BEGINS_WITH(last, "POWER_SUPPLY_ENERGY_FULL=") ||
+ BEGINS_WITH(last, "POWER_SUPPLY_CHARGE_FULL="))
batt_info->full_last = atoi(walk + 1);
}
* 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 && voltage != -1) {
- batt_info->present_rate = (((float)voltage / 1000.0) * ((float)batt_info->present_rate / 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));
- batt_info->full_last = (((float)voltage / 1000.0) * ((float)batt_info->full_last / 1000.0));
+ if (!watt_as_unit && voltage >= 0) {
+ if (batt_info->present_rate > 0) {
+ batt_info->present_rate = (((float)voltage / 1000.0) * ((float)batt_info->present_rate / 1000.0));
+ }
+ if (batt_info->remaining > 0) {
+ batt_info->remaining = (((float)voltage / 1000.0) * ((float)batt_info->remaining / 1000.0));
+ }
+ if (batt_info->full_design > 0) {
+ batt_info->full_design = (((float)voltage / 1000.0) * ((float)batt_info->full_design / 1000.0));
+ }
+ if (batt_info->full_last > 0) {
+ batt_info->full_last = (((float)voltage / 1000.0) * ((float)batt_info->full_last / 1000.0));
+ }
}
-#elif defined(__FreeBSD__) || defined(__FreeBSD_kernel__) || defined(__DragonFly__)
+#elif defined(__DragonFly__)
+ union acpi_battery_ioctl_arg battio;
+ if (acpi_init()) {
+ battio.unit = number;
+ ioctl(acpifd, ACPIIO_BATT_GET_BIF, &battio);
+ batt_info->full_design = battio.bif.dcap;
+ batt_info->full_last = battio.bif.lfcap;
+ battio.unit = number;
+ ioctl(acpifd, ACPIIO_BATT_GET_BATTINFO, &battio);
+ batt_info->percentage_remaining = battio.battinfo.cap;
+ batt_info->present_rate = battio.battinfo.rate;
+ batt_info->seconds_remaining = battio.battinfo.min * 60;
+ switch (battio.battinfo.state) {
+ case 0:
+ batt_info->status = CS_FULL;
+ break;
+ case ACPI_BATT_STAT_CHARGING:
+ batt_info->status = CS_CHARGING;
+ break;
+ case ACPI_BATT_STAT_DISCHARG:
+ batt_info->status = CS_DISCHARGING;
+ break;
+ default:
+ batt_info->status = CS_UNKNOWN;
+ }
+ OUTPUT_FULL_TEXT(format_down);
+ }
+#elif defined(__FreeBSD__) || defined(__FreeBSD_kernel__)
int state;
int sysctl_rslt;
size_t sysctl_size = sizeof(sysctl_rslt);
/*
* Using envsys(4) via sysmon(4).
*/
- bool watt_as_unit = false;
- int voltage = -1;
int fd, rval;
bool is_found = false;
- char *sensor_desc;
- bool is_full = false;
+ char sensor_desc[16];
prop_dictionary_t dict;
prop_array_t array;
prop_object_iterator_t iter2;
prop_object_t obj, obj2, obj3, obj4, obj5;
- asprintf(&sensor_desc, "acpibat%d", number);
+ if (number >= 0)
+ (void)snprintf(sensor_desc, sizeof(sensor_desc), "acpibat%d", number);
fd = open("/dev/sysmon", O_RDONLY);
if (fd < 0) {
/* iterate over the dictionary returned by the kernel */
while ((obj = prop_object_iterator_next(iter)) != NULL) {
/* skip this dict if it's not what we're looking for */
- if (strcmp(sensor_desc,
- prop_dictionary_keysym_cstring_nocopy(obj)) != 0)
- continue;
+ if (number < 0) {
+ /* we want all batteries */
+ if (!BEGINS_WITH(prop_dictionary_keysym_cstring_nocopy(obj),
+ "acpibat"))
+ continue;
+ } else {
+ /* we want a specific battery */
+ if (strcmp(sensor_desc,
+ prop_dictionary_keysym_cstring_nocopy(obj)) != 0)
+ continue;
+ }
is_found = true;
return false;
}
+ struct battery_info batt_buf = {
+ .full_design = 0,
+ .full_last = 0,
+ .remaining = 0,
+ .present_rate = 0,
+ .status = CS_UNKNOWN,
+ };
+ int voltage = -1;
+ bool watt_as_unit = false;
+
/* iterate over array of dicts specific to target battery */
while ((obj2 = prop_object_iterator_next(iter2)) != NULL) {
obj3 = prop_dictionary_get(obj2, "description");
obj3 = prop_dictionary_get(obj2, "cur-value");
if (prop_number_integer_value(obj3))
- batt_info->status = CS_CHARGING;
+ batt_buf.status = CS_CHARGING;
else
- batt_info->status = CS_DISCHARGING;
+ batt_buf.status = CS_DISCHARGING;
} else if (strcmp("charge", prop_string_cstring_nocopy(obj3)) == 0) {
obj3 = prop_dictionary_get(obj2, "cur-value");
obj4 = prop_dictionary_get(obj2, "max-value");
obj5 = prop_dictionary_get(obj2, "type");
- batt_info->remaining = prop_number_integer_value(obj3);
- batt_info->full_design = prop_number_integer_value(obj4);
-
- if (batt_info->remaining == batt_info->full_design)
- is_full = true;
+ batt_buf.remaining = prop_number_integer_value(obj3);
+ batt_buf.full_design = prop_number_integer_value(obj4);
if (strcmp("Ampere hour", prop_string_cstring_nocopy(obj5)) == 0)
watt_as_unit = false;
watt_as_unit = true;
} else if (strcmp("discharge rate", prop_string_cstring_nocopy(obj3)) == 0) {
obj3 = prop_dictionary_get(obj2, "cur-value");
- batt_info->present_rate = prop_number_integer_value(obj3);
+ batt_buf.present_rate = prop_number_integer_value(obj3);
} else if (strcmp("charge rate", prop_string_cstring_nocopy(obj3)) == 0) {
obj3 = prop_dictionary_get(obj2, "cur-value");
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");
- batt_info->full_last = prop_number_integer_value(obj3);
+ batt_buf.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);
}
}
prop_object_iterator_release(iter2);
+
+ if (!watt_as_unit && voltage != -1) {
+ batt_buf.present_rate = (((float)voltage / 1000.0) * ((float)batt_buf.present_rate / 1000.0));
+ batt_buf.remaining = (((float)voltage / 1000.0) * ((float)batt_buf.remaining / 1000.0));
+ batt_buf.full_design = (((float)voltage / 1000.0) * ((float)batt_buf.full_design / 1000.0));
+ batt_buf.full_last = (((float)voltage / 1000.0) * ((float)batt_buf.full_last / 1000.0));
+ }
+
+ if (batt_buf.remaining == batt_buf.full_design)
+ batt_buf.status = CS_FULL;
+
+ add_battery_info(batt_info, &batt_buf);
}
prop_object_iterator_release(iter);
return false;
}
- if (!watt_as_unit && voltage != -1) {
- batt_info->present_rate = (((float)voltage / 1000.0) * ((float)batt_info->present_rate / 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));
- batt_info->full_last = (((float)voltage / 1000.0) * ((float)batt_info->full_last / 1000.0));
+ batt_info->present_rate = abs(batt_info->present_rate);
+#endif
+
+ return true;
+}
+
+/*
+ * Populate batt_info with aggregate information about all batteries.
+ * Returns false on error, and an error message will have been written.
+ */
+static bool slurp_all_batteries(struct battery_info *batt_info, yajl_gen json_gen, char *buffer, const char *path, const char *format_down) {
+#if defined(LINUX)
+ char *outwalk = buffer;
+ bool is_found = false;
+
+ char *placeholder;
+ char *globpath = sstrdup(path);
+ if ((placeholder = strstr(path, "%d")) != NULL) {
+ char *globplaceholder = globpath + (placeholder - path);
+ *globplaceholder = '*';
+ strcpy(globplaceholder + 1, placeholder + 2);
}
- if (is_full)
- batt_info->status = CS_FULL;
+ if (!strcmp(globpath, path)) {
+ OUTPUT_FULL_TEXT("no '%d' in battery path");
+ return false;
+ }
+
+ glob_t globbuf;
+ if (glob(globpath, 0, NULL, &globbuf) == 0) {
+ for (size_t i = 0; i < globbuf.gl_pathc; i++) {
+ /* Probe to see if there is such a battery. */
+ struct battery_info batt_buf = {
+ .full_design = 0,
+ .full_last = 0,
+ .remaining = 0,
+ .present_rate = 0,
+ .status = CS_UNKNOWN,
+ };
+ if (!slurp_battery_info(&batt_buf, json_gen, buffer, i, globbuf.gl_pathv[i], format_down)) {
+ globfree(&globbuf);
+ free(globpath);
+ return false;
+ }
+
+ is_found = true;
+ add_battery_info(batt_info, &batt_buf);
+ }
+ globfree(&globbuf);
+ }
+ free(globpath);
+
+ if (!is_found) {
+ OUTPUT_FULL_TEXT(format_down);
+ return false;
+ }
+
+ batt_info->present_rate = abs(batt_info->present_rate);
+#else
+ /* FreeBSD and OpenBSD only report aggregates. NetBSD always
+ * iterates through all batteries, so it's more efficient to
+ * aggregate in slurp_battery_info. */
+ return slurp_battery_info(batt_info, json_gen, buffer, -1, path, format_down);
#endif
return true;
struct battery_info batt_info = {
.full_design = -1,
.full_last = -1,
+ .remaining = -1,
.present_rate = -1,
.seconds_remaining = -1,
.percentage_remaining = -1,
- .status = CS_DISCHARGING,
+ .status = CS_UNKNOWN,
};
bool colorful_output = false;
/* These OSes report battery stats in whole percent. */
integer_battery_capacity = true;
#endif
-#if defined(__FreeBSD__) || defined(__FreeBSD_kernel__) || defined(__DragonFly__)
+#if defined(__FreeBSD__) || defined(__FreeBSD_kernel__) || defined(__DragonFly__) || defined(__OpenBSD__)
/* These OSes report battery time in minutes. */
hide_seconds = true;
#endif
- if (!slurp_battery_info(&batt_info, json_gen, buffer, number, path, format_down))
- return;
+ if (number < 0) {
+ if (!slurp_all_batteries(&batt_info, json_gen, buffer, path, format_down))
+ return;
+ } else {
+ if (!slurp_battery_info(&batt_info, json_gen, buffer, number, path, format_down))
+ return;
+ }
- int full = (last_full_capacity ? batt_info.full_last : batt_info.full_design);
- if (full < 0 && batt_info.percentage_remaining < 0) {
+ // *Choose* a measure of the 'full' battery. It is whichever is better of
+ // the battery's (hardware-given) design capacity (batt_info.full_design)
+ // and the battery's last known good charge (batt_info.full_last).
+ // We prefer the design capacity, but use the last capacity if we don't have it,
+ // or if we are asked to (last_full_capacity == true); but similarly we use
+ // the design capacity if we don't have the last capacity.
+ // If we don't have either then both full_design and full_last <= 0,
+ // which implies full <= 0, which bails out on the following line.
+ int full = batt_info.full_design;
+ if (full <= 0 || (last_full_capacity && batt_info.full_last > 0)) {
+ full = batt_info.full_last;
+ }
+ if (full <= 0 && batt_info.remaining < 0 && batt_info.percentage_remaining < 0) {
/* We have no physical measurements and no estimates. Nothing
* much we can report, then. */
OUTPUT_FULL_TEXT(format_down);
if (*walk != '%') {
*(outwalk++) = *walk;
- continue;
- }
- if (BEGINS_WITH(walk + 1, "status")) {
+ } else if (BEGINS_WITH(walk + 1, "status")) {
const char *statusstr;
switch (batt_info.status) {
case CS_CHARGING:
outwalk += sprintf(outwalk, "%s", statusstr);
walk += strlen("status");
+
} else if (BEGINS_WITH(walk + 1, "percentage")) {
if (integer_battery_capacity) {
outwalk += sprintf(outwalk, "%.00f%s", batt_info.percentage_remaining, pct_mark);
outwalk += sprintf(outwalk, "%.02f%s", batt_info.percentage_remaining, pct_mark);
}
walk += strlen("percentage");
+
} else if (BEGINS_WITH(walk + 1, "remaining")) {
if (batt_info.seconds_remaining >= 0) {
int seconds, hours, minutes;
}
walk += strlen("remaining");
EAT_SPACE_FROM_OUTPUT_IF_NO_OUTPUT();
+
} else if (BEGINS_WITH(walk + 1, "emptytime")) {
if (batt_info.seconds_remaining >= 0) {
time_t empty_time = time(NULL) + batt_info.seconds_remaining;
+ set_timezone(NULL); /* Use local time. */
struct tm *empty_tm = localtime(&empty_time);
if (hide_seconds)
}
walk += strlen("emptytime");
EAT_SPACE_FROM_OUTPUT_IF_NO_OUTPUT();
+
} else if (BEGINS_WITH(walk + 1, "consumption")) {
if (batt_info.present_rate >= 0)
outwalk += sprintf(outwalk, "%1.2fW", batt_info.present_rate / 1e6);
walk += strlen("consumption");
EAT_SPACE_FROM_OUTPUT_IF_NO_OUTPUT();
+
+ } else {
+ *(outwalk++) = '%';
}
}