static int
sensor_threshold_event_handler(ipmi_sensor_t *sensor,
enum ipmi_event_dir_e dir,
enum ipmi_thresh_e threshold,
enum ipmi_event_value_dir_e high_low,
enum ipmi_value_present_e value_present,
unsigned int raw_value,
double value,
void *cb_data,
ipmi_event_t *event)
{
ipmi_cmd_info_t *evi;
char sensor_name[IPMI_SENSOR_NAME_LEN];
int rv;
char *errstr;
ipmi_sensor_get_name(sensor, sensor_name, sizeof(sensor_name));
evi = ipmi_cmdlang_alloc_event_info();
if (!evi) {
rv = ENOMEM;
errstr = "Out of memory";
goto out_err;
}
ipmi_cmdlang_out(evi, "Object Type", "Sensor");
ipmi_cmdlang_out(evi, "Name", sensor_name);
ipmi_cmdlang_out(evi, "Operation", "Event");
ipmi_cmdlang_out(evi, "Threshold", ipmi_get_threshold_string(threshold));
ipmi_cmdlang_out(evi, "High/Low", ipmi_get_value_dir_string(high_low));
ipmi_cmdlang_out(evi, "Direction", ipmi_get_event_dir_string(dir));
switch (value_present) {
case IPMI_BOTH_VALUES_PRESENT:
ipmi_cmdlang_out_double(evi, "Value", value);
/* FALLTHRU */
case IPMI_RAW_VALUE_PRESENT:
ipmi_cmdlang_out_int(evi, "Raw Value", raw_value);
break;
default:
break;
}
if (event) {
ipmi_cmdlang_out(evi, "Event", NULL);
ipmi_cmdlang_down(evi);
ipmi_cmdlang_event_out(event, evi);
ipmi_cmdlang_up(evi);
}
ipmi_cmdlang_cmd_info_put(evi);
return IPMI_EVENT_NOT_HANDLED;
out_err:
ipmi_cmdlang_global_err(sensor_name,
"cmd_sensor.c(sensor_threshold_event_handler)",
errstr, rv);
if (evi)
ipmi_cmdlang_cmd_info_put(evi);
return IPMI_EVENT_NOT_HANDLED;
}
static void
sensor_get_event_enables_done(ipmi_sensor_t *sensor,
int err,
ipmi_event_state_t *states,
void *cb_data)
{
ipmi_cmd_info_t *cmd_info = cb_data;
ipmi_cmdlang_t *cmdlang = ipmi_cmdinfo_get_cmdlang(cmd_info);
char sensor_name[IPMI_SENSOR_NAME_LEN];
int rv;
int val;
ipmi_cmdlang_lock(cmd_info);
if (err) {
cmdlang->errstr = "Error reading sensor event enables";
cmdlang->err = err;
ipmi_sensor_get_name(sensor, cmdlang->objstr,
cmdlang->objstr_len);
cmdlang->location = "cmd_sensor.c(sensor_get_event_enables_done)";
goto out;
}
ipmi_sensor_get_name(sensor, sensor_name, sizeof(sensor_name));
ipmi_cmdlang_out(cmd_info, "Sensor", NULL);
ipmi_cmdlang_down(cmd_info);
ipmi_cmdlang_out(cmd_info, "Name", sensor_name);
ipmi_cmdlang_out_bool(cmd_info, "Event Messages Enabled",
ipmi_event_state_get_events_enabled(states));
ipmi_cmdlang_out_bool(cmd_info, "Sensor Scanning Enabled",
ipmi_event_state_get_scanning_enabled(states));
ipmi_cmdlang_out_bool(cmd_info, "Busy",
ipmi_event_state_get_busy(states));
if (ipmi_sensor_get_event_reading_type(sensor)
== IPMI_EVENT_READING_TYPE_THRESHOLD)
{
enum ipmi_thresh_e thresh;
enum ipmi_event_value_dir_e value_dir;
enum ipmi_event_dir_e dir;
for (thresh = IPMI_LOWER_NON_CRITICAL;
thresh <= IPMI_UPPER_NON_RECOVERABLE;
thresh++)
{
for (value_dir = IPMI_GOING_LOW;
value_dir <= IPMI_GOING_HIGH;
value_dir++)
{
for (dir = IPMI_ASSERTION;
dir <= IPMI_DEASSERTION;
dir++)
{
char th_name[50];
rv = ipmi_sensor_threshold_event_supported(sensor,
thresh,
value_dir,
dir,
&val);
if (rv || !val) continue;
ipmi_cmdlang_out(cmd_info, "Threshold", NULL);
ipmi_cmdlang_down(cmd_info);
snprintf(th_name, sizeof(th_name), "%s %s %s",
ipmi_get_threshold_string(thresh),
ipmi_get_value_dir_string(value_dir),
ipmi_get_event_dir_string(dir));
ipmi_cmdlang_out(cmd_info, "Name", th_name);
ipmi_cmdlang_out_bool(cmd_info, "Enabled",
ipmi_is_threshold_event_set
(states, thresh, value_dir, dir));
ipmi_cmdlang_up(cmd_info);
}
}
}
} else {
int offset;
const char *str;
for (offset=0; offset<15; offset++) {
rv = ipmi_sensor_discrete_event_readable(sensor, offset, &val);
if (rv || !val)
continue;
ipmi_cmdlang_out(cmd_info, "Event", NULL);
ipmi_cmdlang_down(cmd_info);
ipmi_cmdlang_out_int(cmd_info, "Offset", offset);
str = ipmi_sensor_reading_name_string(sensor, offset);
if (strcmp(str, "unknown") != 0)
ipmi_cmdlang_out(cmd_info, "Name", str);
rv = ipmi_sensor_discrete_event_supported(sensor,
offset,
IPMI_ASSERTION,
&val);
if (!rv && val) {
ipmi_cmdlang_out_bool(cmd_info, "Assertion Enabled",
ipmi_is_discrete_event_set
(states, offset, IPMI_ASSERTION));
}
rv = ipmi_sensor_discrete_event_supported(sensor,
offset,
IPMI_DEASSERTION,
&val);
if (!rv && val) {
ipmi_cmdlang_out_bool(cmd_info, "Deassertion Enabled",
ipmi_is_discrete_event_set
(states, offset, IPMI_DEASSERTION));
}
ipmi_cmdlang_up(cmd_info);
}
}
ipmi_cmdlang_up(cmd_info);
out:
ipmi_cmdlang_unlock(cmd_info);
ipmi_cmdlang_cmd_info_put(cmd_info);
}
static void
sensor_dump(ipmi_sensor_t *sensor, ipmi_cmd_info_t *cmd_info)
{
ipmi_cmdlang_t *cmdlang = ipmi_cmdinfo_get_cmdlang(cmd_info);
int num, lun;
char *str;
const char *cstr;
int event_support;
int event_reading_type;
int len;
int rv;
int val;
event_reading_type = ipmi_sensor_get_event_reading_type(sensor);
ipmi_sensor_get_num(sensor, &lun, &num);
ipmi_cmdlang_out_int(cmd_info, "LUN", lun);
ipmi_cmdlang_out_int(cmd_info, "Number", num);
ipmi_cmdlang_out_int(cmd_info, "Event Reading Type",
ipmi_sensor_get_event_reading_type(sensor));
ipmi_cmdlang_out(cmd_info, "Event Reading Type Name",
ipmi_sensor_get_event_reading_type_string(sensor));
ipmi_cmdlang_out_int(cmd_info, "Type",
ipmi_sensor_get_sensor_type(sensor));
ipmi_cmdlang_out(cmd_info, "Type Name",
ipmi_sensor_get_sensor_type_string(sensor));
val = ipmi_sensor_get_sensor_direction(sensor);
if (val != IPMI_SENSOR_DIRECTION_UNSPECIFIED)
ipmi_cmdlang_out(cmd_info, "Direction",
ipmi_get_sensor_direction_string(val));
event_support = ipmi_sensor_get_event_support(sensor);
switch (event_support) {
case IPMI_EVENT_SUPPORT_PER_STATE:
ipmi_cmdlang_out(cmd_info, "Event Support", "per state");
break;
case IPMI_EVENT_SUPPORT_ENTIRE_SENSOR:
ipmi_cmdlang_out(cmd_info, "Event Support", "entire sensor");
break;
case IPMI_EVENT_SUPPORT_GLOBAL_ENABLE:
ipmi_cmdlang_out(cmd_info, "Event Support", "global");
break;
default:
break;
}
ipmi_cmdlang_out_bool(cmd_info, "Init Scanning",
ipmi_sensor_get_sensor_init_scanning(sensor));
ipmi_cmdlang_out_bool(cmd_info, "Init Events",
ipmi_sensor_get_sensor_init_events(sensor));
ipmi_cmdlang_out_bool(cmd_info, "Init Thresholds",
ipmi_sensor_get_sensor_init_thresholds(sensor));
ipmi_cmdlang_out_bool(cmd_info, "Init Hysteresis",
ipmi_sensor_get_sensor_init_hysteresis(sensor));
ipmi_cmdlang_out_bool(cmd_info, "Init Type",
ipmi_sensor_get_sensor_init_type(sensor));
ipmi_cmdlang_out_bool(cmd_info, "Init Power Up Events",
ipmi_sensor_get_sensor_init_pu_events(sensor));
ipmi_cmdlang_out_bool(cmd_info, "Init Power Up Scanning",
ipmi_sensor_get_sensor_init_pu_scanning(sensor));
ipmi_cmdlang_out_bool(cmd_info, "Ignore If No Entity",
ipmi_sensor_get_ignore_if_no_entity(sensor));
ipmi_cmdlang_out_bool(cmd_info, "Auto Rearm",
ipmi_sensor_get_supports_auto_rearm(sensor));
ipmi_cmdlang_out_int(cmd_info, "OEM1",
ipmi_sensor_get_oem1(sensor));
len = ipmi_sensor_get_id_length(sensor);
if (len) {
str = ipmi_mem_alloc(len);
if (!str) {
cmdlang->err = ENOMEM;
cmdlang->errstr = "Out of memory";
goto out_err;
}
len = ipmi_sensor_get_id(sensor, str, len);
ipmi_cmdlang_out_type(cmd_info, "Id",
ipmi_sensor_get_id_type(sensor),
str, len);
ipmi_mem_free(str);
}
if (event_reading_type == IPMI_EVENT_READING_TYPE_THRESHOLD) {
int access = ipmi_sensor_get_threshold_access(sensor);
enum ipmi_thresh_e thresh;
enum ipmi_event_value_dir_e value_dir;
enum ipmi_event_dir_e dir;
int rv;
char th_name[50];
double dval;
ipmi_cmdlang_out(cmd_info, "Threshold Access",
ipmi_get_threshold_access_support_string(access));
for (thresh = IPMI_LOWER_NON_CRITICAL;
thresh <= IPMI_UPPER_NON_RECOVERABLE;
thresh++)
{
rv = ipmi_sensor_threshold_reading_supported(sensor, thresh, &val);
if ((rv) || !val)
continue;
ipmi_cmdlang_out(cmd_info, "Threshold", NULL);
ipmi_cmdlang_down(cmd_info);
ipmi_cmdlang_out(cmd_info, "Name",
ipmi_get_threshold_string(thresh));
rv = ipmi_sensor_threshold_readable(sensor, thresh, &val);
if (rv)
val = 0;
ipmi_cmdlang_out_bool(cmd_info, "Readable", val);
rv = ipmi_sensor_threshold_settable(sensor, thresh, &val);
if (rv)
val = 0;
ipmi_cmdlang_out_bool(cmd_info, "Settable", val);
for (value_dir = IPMI_GOING_LOW;
value_dir <= IPMI_GOING_HIGH;
value_dir++)
{
for (dir = IPMI_ASSERTION;
dir <= IPMI_DEASSERTION;
dir++)
{
rv = ipmi_sensor_threshold_event_supported(sensor,
thresh,
value_dir,
dir,
&val);
if (rv || !val) continue;
snprintf(th_name, sizeof(th_name), "%s %s",
ipmi_get_value_dir_string(value_dir),
ipmi_get_event_dir_string(dir));
ipmi_cmdlang_out(cmd_info, "Supports", th_name);
}
}
ipmi_cmdlang_up(cmd_info);
}
val = ipmi_sensor_get_hysteresis_support(sensor);
ipmi_cmdlang_out(cmd_info, "Hysteresis Support",
ipmi_get_hysteresis_support_string(val));
#if 0
/* FIXME - no accuracy handling */
int ipmi_sensor_get_accuracy(ipmi_sensor_t *sensor, int val,
double *accuracy);
#endif
rv = ipmi_sensor_get_nominal_reading(sensor, &dval);
if (!rv)
ipmi_cmdlang_out_double(cmd_info, "Nominal Reading", dval);
rv = ipmi_sensor_get_normal_max(sensor, &dval);
if (!rv)
ipmi_cmdlang_out_double(cmd_info, "Normal Max", dval);
rv = ipmi_sensor_get_normal_min(sensor, &dval);
if (!rv)
ipmi_cmdlang_out_double(cmd_info, "Normal Min", dval);
rv = ipmi_sensor_get_sensor_max(sensor, &dval);
if (!rv)
ipmi_cmdlang_out_double(cmd_info, "Sensor Max", dval);
rv = ipmi_sensor_get_sensor_min(sensor, &dval);
if (!rv)
ipmi_cmdlang_out_double(cmd_info, "Sensor Min", dval);
ipmi_cmdlang_out_int(cmd_info, "Base Unit",
ipmi_sensor_get_base_unit(sensor));
ipmi_cmdlang_out(cmd_info, "Base Unit Name",
ipmi_sensor_get_base_unit_string(sensor));
cstr = ipmi_sensor_get_rate_unit_string(sensor);
if (strlen(cstr)) {
ipmi_cmdlang_out_int(cmd_info, "Rate Unit",
ipmi_sensor_get_rate_unit(sensor));
ipmi_cmdlang_out(cmd_info, "Rate Unit Name", cstr);
}
switch (ipmi_sensor_get_modifier_unit_use(sensor)) {
case IPMI_MODIFIER_UNIT_BASE_DIV_MOD:
ipmi_cmdlang_out(cmd_info, "Modifier Use", "/");
ipmi_cmdlang_out_int(cmd_info, "Modifier Unit",
ipmi_sensor_get_modifier_unit(sensor));
ipmi_cmdlang_out(cmd_info, "Modifier Unit Name",
ipmi_sensor_get_modifier_unit_string(sensor));
break;
case IPMI_MODIFIER_UNIT_BASE_MULT_MOD:
ipmi_cmdlang_out(cmd_info, "Modifier Use", "*");
ipmi_cmdlang_out_int(cmd_info, "Modifier Unit",
ipmi_sensor_get_modifier_unit(sensor));
ipmi_cmdlang_out(cmd_info, "Modifier Unit Name",
ipmi_sensor_get_modifier_unit_string(sensor));
break;
default:
break;
}
if (ipmi_sensor_get_percentage(sensor))
ipmi_cmdlang_out(cmd_info, "Percentage", "%");
} else {
int event;
enum ipmi_event_dir_e dir;
for (event=0; event<15; event++) {
rv = ipmi_sensor_discrete_event_readable(sensor, event, &val);
if (rv || !val)
continue;
ipmi_cmdlang_out(cmd_info, "Event", NULL);
ipmi_cmdlang_down(cmd_info);
ipmi_cmdlang_out_int(cmd_info, "Offset", event);
cstr = ipmi_sensor_reading_name_string(sensor, event);
if (strcmp(cstr, "unknown") != 0)
ipmi_cmdlang_out(cmd_info, "Name", cstr);
for (dir = IPMI_ASSERTION;
dir <= IPMI_DEASSERTION;
dir++)
{
rv = ipmi_sensor_discrete_event_supported(sensor,
event,
dir,
&val);
if (rv || !val) continue;
ipmi_cmdlang_out(cmd_info, "Supports",
ipmi_get_event_dir_string(dir));
}
ipmi_cmdlang_up(cmd_info);
}
}
return;
out_err:
ipmi_sensor_get_name(sensor, cmdlang->objstr,
cmdlang->objstr_len);
cmdlang->location = "cmd_sensor.c(sensor_dump)";
}
static void
got_events(ipmi_sensor_t *sensor,
int err,
ipmi_event_state_t *states,
void *cb_data)
{
sdata_t *sdata = cb_data;
int rv;
if (err) {
printf("Error 0x%x getting events for sensor %s\n", err, sdata->name);
goto out_err;
}
/* Turn on the general events for a sensor, since this at
least supports per-sensor enables. */
ipmi_event_state_set_events_enabled(sdata->es, 1);
ipmi_event_state_set_scanning_enabled(sdata->es, 1);
printf("Sensor %s event settings:\n", sdata->name);
if (sdata->state_sup != IPMI_EVENT_SUPPORT_PER_STATE) {
/* No per-state sensors, just do the global enable. */
} else if (ipmi_sensor_get_event_reading_type(sensor)
== IPMI_EVENT_READING_TYPE_THRESHOLD)
{
/* Check each event, print out the current state, and turn it
on in the events to set if it is available. */
enum ipmi_event_value_dir_e value_dir;
enum ipmi_event_dir_e dir;
enum ipmi_thresh_e thresh;
int val;
for (value_dir=IPMI_GOING_LOW; value_dir<=IPMI_GOING_HIGH; value_dir++)
{
for (dir=IPMI_ASSERTION; dir<=IPMI_DEASSERTION; dir++) {
for (thresh=IPMI_LOWER_NON_CRITICAL;
thresh<=IPMI_UPPER_NON_RECOVERABLE;
thresh++)
{
char *v;
rv = ipmi_sensor_threshold_event_supported
(sensor, thresh, value_dir, dir, &val);
if (rv || !val)
continue;
if (ipmi_is_threshold_event_set(states, thresh,
value_dir, dir))
v = "";
else
v = " not";
printf(" %s %s %s was%s enabled\n",
ipmi_get_threshold_string(thresh),
ipmi_get_value_dir_string(value_dir),
ipmi_get_event_dir_string(dir),
v);
ipmi_threshold_event_set(sdata->es, thresh,
value_dir, dir);
}
}
}
} else {
/* Check each event, print out the current state, and turn it
on in the events to set if it is available. */
enum ipmi_event_dir_e dir;
int i;
for (dir=IPMI_ASSERTION; dir<=IPMI_DEASSERTION; dir++) {
for (i=0; i<15; i++) {
char *v;
int val;
rv = ipmi_sensor_discrete_event_supported
(sensor, i, dir, &val);
if (rv || !val)
continue;
if (ipmi_is_discrete_event_set(states, i, dir))
v = "";
else
v = " not";
printf(" bit %d %s was%s enabled\n",
i,
ipmi_get_event_dir_string(dir),
v);
ipmi_discrete_event_set(sdata->es, i, dir);
}
}
}
rv = ipmi_sensor_set_event_enables(sensor, sdata->es,
event_set_done, sdata);
if (rv) {
printf("Error 0x%x enabling events for sensor %s\n", err, sdata->name);
goto out_err;
}
return;
out_err:
release_sdata(sdata);
}
