// vim:ts=4:sw=4:expandtab #include #include #include #include #include #include #include #include "i3status.h" #if defined(__FreeBSD__) || defined(__FreeBSD_kernel__) || defined(__DragonFly__) #include #include #include #endif #if defined(__OpenBSD__) #include #include #include #include #endif #if defined(__NetBSD__) #include #include #include #endif /* * Get battery information from /sys. Note that it uses the design capacity to * calculate the percentage, not the last full capacity, so you can see how * worn off your battery is. * */ void print_battery_info(yajl_gen json_gen, char *buffer, int number, const char *path, const char *format, const char *format_down, const char *status_chr, const char *status_bat, const char *status_unk, const char *status_full, int low_threshold, char *threshold_type, bool last_full_capacity, bool integer_battery_capacity, bool hide_seconds) { char buf[1024]; const char *walk, *last; char *outwalk = buffer; bool watt_as_unit = false; int full_design = -1, remaining = -1, present_rate = -1, voltage = -1, seconds_remaining = -1; float percentage_remaining = -1; charging_status_t status = CS_DISCHARGING; static char batpath[512]; sprintf(batpath, path, number); INSTANCE(batpath); #if defined(LINUX) if (!slurp(batpath, buf, sizeof(buf))) { OUTPUT_FULL_TEXT(format_down); return; } for (walk = buf, last = buf; (walk - buf) < 1024; walk++) { if (*walk == '\n') { last = walk + 1; continue; } if (*walk != '=') continue; if (BEGINS_WITH(last, "POWER_SUPPLY_ENERGY_NOW")) { watt_as_unit = true; remaining = atoi(walk + 1); } else if (BEGINS_WITH(last, "POWER_SUPPLY_CHARGE_NOW")) { watt_as_unit = false; remaining = atoi(walk + 1); } else if (BEGINS_WITH(last, "POWER_SUPPLY_CURRENT_NOW")) present_rate = abs(atoi(walk + 1)); 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")) present_rate = abs(atoi(walk + 1)); else if (BEGINS_WITH(last, "POWER_SUPPLY_STATUS=Charging")) status = CS_CHARGING; else if (BEGINS_WITH(last, "POWER_SUPPLY_STATUS=Full")) status = CS_FULL; else if (BEGINS_WITH(last, "POWER_SUPPLY_STATUS=Discharging")) status = CS_DISCHARGING; else if (BEGINS_WITH(last, "POWER_SUPPLY_STATUS=")) 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); } } /* 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) { present_rate = (((float)voltage / 1000.0) * ((float)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)); } } if ((full_design == -1) || (remaining == -1)) { OUTPUT_FULL_TEXT(format_down); return; } percentage_remaining = (((float)remaining / (float)full_design) * 100); /* Some batteries report POWER_SUPPLY_CHARGE_NOW= 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 * value to 100%, as that makes more sense. * See http://bugs.debian.org/785398 */ if (last_full_capacity && percentage_remaining > 100) { percentage_remaining = 100; } if (present_rate > 0 && status != CS_FULL) { float remaining_time; if (status == CS_CHARGING) remaining_time = ((float)full_design - (float)remaining) / (float)present_rate; else if (status == CS_DISCHARGING) remaining_time = ((float)remaining / (float)present_rate); else remaining_time = 0; seconds_remaining = (int)(remaining_time * 3600.0); } #elif defined(__FreeBSD__) || defined(__FreeBSD_kernel__) || defined(__DragonFly__) int state; int sysctl_rslt; size_t sysctl_size = sizeof(sysctl_rslt); if (sysctlbyname(BATT_LIFE, &sysctl_rslt, &sysctl_size, NULL, 0) != 0) { OUTPUT_FULL_TEXT(format_down); return; } integer_battery_capacity = true; percentage_remaining = sysctl_rslt; if (sysctlbyname(BATT_TIME, &sysctl_rslt, &sysctl_size, NULL, 0) != 0) { OUTPUT_FULL_TEXT(format_down); return; } hide_seconds = true; seconds_remaining = sysctl_rslt * 60; if (sysctlbyname(BATT_STATE, &sysctl_rslt, &sysctl_size, NULL, 0) != 0) { OUTPUT_FULL_TEXT(format_down); return; } state = sysctl_rslt; if (state == 0 && percentage_remaining == 100) status = CS_FULL; else if ((state & ACPI_BATT_STAT_CHARGING) && percentage_remaining < 100) status = CS_CHARGING; else status = CS_DISCHARGING; full_design = sysctl_rslt; #elif defined(__OpenBSD__) /* * We're using apm(4) here, which is the interface to acpi(4) on amd64/i386 and * the generic interface on macppc/sparc64/zaurus, instead of using sysctl(3) and * probing acpi(4) devices. */ struct apm_power_info apm_info; int apm_fd; apm_fd = open("/dev/apm", O_RDONLY); if (apm_fd < 0) { OUTPUT_FULL_TEXT("can't open /dev/apm"); return; } if (ioctl(apm_fd, APM_IOC_GETPOWER, &apm_info) < 0) OUTPUT_FULL_TEXT("can't read power info"); close(apm_fd); /* Don't bother to go further if there's no battery present. */ if ((apm_info.battery_state == APM_BATTERY_ABSENT) || (apm_info.battery_state == APM_BATT_UNKNOWN)) { OUTPUT_FULL_TEXT(format_down); return; } switch (apm_info.ac_state) { case APM_AC_OFF: status = CS_DISCHARGING; break; case APM_AC_ON: status = CS_CHARGING; break; default: /* If we don't know what's going on, just assume we're discharging. */ status = CS_DISCHARGING; break; } integer_battery_capacity = true; percentage_remaining = apm_info.battery_life; /* Can't give a meaningful value for remaining minutes if we're charging. */ if (status != CS_CHARGING) { seconds_remaining = apm_info.minutes_left * 60; } if (colorful_output) END_COLOR; #elif defined(__NetBSD__) /* * Using envsys(4) via sysmon(4). */ int fd, rval, last_full_cap; bool is_found = false; char *sensor_desc; bool is_full = false; prop_dictionary_t dict; prop_array_t array; prop_object_iterator_t iter; prop_object_iterator_t iter2; prop_object_t obj, obj2, obj3, obj4, obj5; asprintf(&sensor_desc, "acpibat%d", number); fd = open("/dev/sysmon", O_RDONLY); if (fd < 0) { OUTPUT_FULL_TEXT("can't open /dev/sysmon"); return; } rval = prop_dictionary_recv_ioctl(fd, ENVSYS_GETDICTIONARY, &dict); if (rval == -1) { close(fd); return; } if (prop_dictionary_count(dict) == 0) { prop_object_release(dict); close(fd); return; } iter = prop_dictionary_iterator(dict); if (iter == NULL) { prop_object_release(dict); close(fd); } /* 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 ((strlen(prop_dictionary_keysym_cstring_nocopy(obj)) == strlen(sensor_desc)) && (strncmp(sensor_desc, prop_dictionary_keysym_cstring_nocopy(obj), strlen(sensor_desc)) != 0)) continue; is_found = true; array = prop_dictionary_get_keysym(dict, obj); if (prop_object_type(array) != PROP_TYPE_ARRAY) { prop_object_iterator_release(iter); prop_object_release(dict); close(fd); return; } iter2 = prop_array_iterator(array); if (!iter2) { prop_object_iterator_release(iter); prop_object_release(dict); close(fd); return; } /* iterate over array of dicts specific to target battery */ while ((obj2 = prop_object_iterator_next(iter2)) != NULL) { obj3 = prop_dictionary_get(obj2, "description"); if (obj3 && strlen(prop_string_cstring_nocopy(obj3)) == 8 && strncmp("charging", prop_string_cstring_nocopy(obj3), 8) == 0) { obj3 = prop_dictionary_get(obj2, "cur-value"); if (prop_number_integer_value(obj3)) status = CS_CHARGING; else status = CS_DISCHARGING; continue; } if (obj3 && strlen(prop_string_cstring_nocopy(obj3)) == 6 && strncmp("charge", prop_string_cstring_nocopy(obj3), 6) == 0) { obj3 = prop_dictionary_get(obj2, "cur-value"); 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); if (remaining == full_design) is_full = true; if (strncmp("Ampere hour", prop_string_cstring_nocopy(obj5), 11) == 0) watt_as_unit = false; else watt_as_unit = true; continue; } if (obj3 && strlen(prop_string_cstring_nocopy(obj3)) == 14 && strncmp("discharge rate", prop_string_cstring_nocopy(obj3), 14) == 0) { obj3 = prop_dictionary_get(obj2, "cur-value"); present_rate = prop_number_integer_value(obj3); continue; } if (obj3 && strlen(prop_string_cstring_nocopy(obj3)) == 13 && strncmp("last full cap", prop_string_cstring_nocopy(obj3), 13) == 0) { obj3 = prop_dictionary_get(obj2, "cur-value"); last_full_cap = prop_number_integer_value(obj3); continue; } if (obj3 && strlen(prop_string_cstring_nocopy(obj3)) == 7 && strncmp("voltage", prop_string_cstring_nocopy(obj3), 7) == 0) { obj3 = prop_dictionary_get(obj2, "cur-value"); voltage = prop_number_integer_value(obj3); continue; } } prop_object_iterator_release(iter2); } prop_object_iterator_release(iter); prop_object_release(dict); close(fd); if (!is_found) { OUTPUT_FULL_TEXT(format_down); return; } if (last_full_capacity) full_design = last_full_cap; if (!watt_as_unit) { present_rate = (((float)voltage / 1000.0) * ((float)present_rate / 1000.0)); remaining = (((float)voltage / 1000.0) * ((float)remaining / 1000.0)); full_design = (((float)voltage / 1000.0) * ((float)full_design / 1000.0)); } percentage_remaining = (((float)remaining / (float)full_design) * 100); if (is_full) status = CS_FULL; /* * The envsys(4) ACPI routines do not appear to provide a 'time * remaining' figure, so we must deduce it. */ float remaining_time; if (status == CS_CHARGING) remaining_time = ((float)full_design - (float)remaining) / (float)present_rate; else if (status == CS_DISCHARGING) remaining_time = ((float)remaining / (float)present_rate); else remaining_time = 0; seconds_remaining = (int)(remaining_time * 3600.0); #endif bool colorful_output = false; if (status == CS_DISCHARGING && low_threshold > 0) { if (percentage_remaining >= 0 && strcasecmp(threshold_type, "percentage") == 0 && percentage_remaining < low_threshold) { START_COLOR("color_bad"); colorful_output = true; } else if (seconds_remaining >= 0 && strcasecmp(threshold_type, "time") == 0 && seconds_remaining < 60 * low_threshold) { START_COLOR("color_bad"); colorful_output = true; } } #define EAT_SPACE_FROM_OUTPUT_IF_NO_OUTPUT() \ do { \ if (outwalk == prevoutwalk) { \ if (outwalk > buffer && isspace(outwalk[-1])) \ outwalk--; \ else if (isspace(*(walk + 1))) \ walk++; \ } \ } while (0) for (walk = format; *walk != '\0'; walk++) { char *prevoutwalk = outwalk; if (*walk != '%') { *(outwalk++) = *walk; continue; } if (BEGINS_WITH(walk + 1, "status")) { const char *statusstr; switch (status) { case CS_CHARGING: statusstr = status_chr; break; case CS_DISCHARGING: statusstr = status_bat; break; case CS_FULL: statusstr = status_full; break; default: statusstr = status_unk; } outwalk += sprintf(outwalk, "%s", statusstr); walk += strlen("status"); } else if (BEGINS_WITH(walk + 1, "percentage")) { if (integer_battery_capacity) { outwalk += sprintf(outwalk, "%.00f%s", percentage_remaining, pct_mark); } else { outwalk += sprintf(outwalk, "%.02f%s", percentage_remaining, pct_mark); } walk += strlen("percentage"); } else if (BEGINS_WITH(walk + 1, "remaining")) { if (seconds_remaining >= 0) { int seconds, hours, minutes; hours = seconds_remaining / 3600; seconds = seconds_remaining - (hours * 3600); minutes = seconds / 60; seconds -= (minutes * 60); if (hide_seconds) outwalk += sprintf(outwalk, "%02d:%02d", max(hours, 0), max(minutes, 0)); else outwalk += sprintf(outwalk, "%02d:%02d:%02d", max(hours, 0), max(minutes, 0), max(seconds, 0)); } walk += strlen("remaining"); EAT_SPACE_FROM_OUTPUT_IF_NO_OUTPUT(); } else if (BEGINS_WITH(walk + 1, "emptytime")) { if (seconds_remaining >= 0) { time_t empty_time = time(NULL) + seconds_remaining; struct tm *empty_tm = localtime(&empty_time); if (hide_seconds) outwalk += sprintf(outwalk, "%02d:%02d", max(empty_tm->tm_hour, 0), max(empty_tm->tm_min, 0)); else outwalk += sprintf(outwalk, "%02d:%02d:%02d", max(empty_tm->tm_hour, 0), max(empty_tm->tm_min, 0), max(empty_tm->tm_sec, 0)); } walk += strlen("emptytime"); EAT_SPACE_FROM_OUTPUT_IF_NO_OUTPUT(); } else if (BEGINS_WITH(walk + 1, "consumption")) { if (present_rate >= 0) outwalk += sprintf(outwalk, "%1.2fW", present_rate / 1e6); walk += strlen("consumption"); EAT_SPACE_FROM_OUTPUT_IF_NO_OUTPUT(); } } if (colorful_output) END_COLOR; OUTPUT_FULL_TEXT(buffer); }