includes/discovery/sensors/voltage/apc.inc.php
<?php
// Battery Bus Voltage
// upsHighPrecBatteryActualVoltage
$oids = snmp_get($device, '.1.3.6.1.4.1.318.1.1.1.2.3.4.0', '-OsqnU');
$divisor = 10;
$index = '2.3.4.0';
d_echo($oids . "\n");
if (! $oids) {
// upsAdvBatteryActualVoltage, used in case high precision is not available
$oids = snmp_get($device, '.1.3.6.1.4.1.318.1.1.1.2.2.8.0', '-OsqnU', '');
d_echo($oids . "\n");
$divisor = 1;
$index = '2.2.8.0';
}
if ($oids) {
echo ' Battery Bus ';
[$oid,$current] = explode(' ', $oids);
$type = 'apc';
$descr = 'Battery Bus';
discover_sensor($valid['sensor'], 'voltage', $device, $oid, $index, $type, $descr, $divisor, '1', null, null, null, null, $current / $divisor);
}
unset($oids);
//Three Phase Detection & Support
$phasecount = $pre_cache['apcups_phase_count'];
d_echo($phasecount);
d_echo($pre_cache['apcups_phase_count']);
// Check for three phase UPS devices - else skip to normal discovery
if ($phasecount > 2) {
$oids = snmpwalk_cache_oid($device, 'upsPhaseOutputVoltage', $oids, 'PowerNet-MIB');
$in_oids = snmpwalk_cache_oid($device, 'upsPhaseInputVoltage', $in_oids, 'PowerNet-MIB');
foreach ($oids as $index => $data) {
$type = 'apcUPS';
$descr = 'Phase ' . substr($index, -1) . ' Output';
$voltage_oid = '.1.3.6.1.4.1.318.1.1.1.9.3.3.1.3.' . $index;
$divisor = 1;
$voltage = $data['upsPhaseOutputVoltage'] / $divisor;
if ($voltage >= 0) {
discover_sensor($valid['sensor'], 'voltage', $device, $voltage_oid, $index, $type, $descr, $divisor, 1, null, null, null, null, $voltage);
}
}
unset($index);
unset($data);
foreach ($in_oids as $index => $data) {
$type = 'apcUPS';
$voltage_oid = '.1.3.6.1.4.1.318.1.1.1.9.2.3.1.3.' . $index;
$divisor = 1;
$voltage = $data['upsPhaseInputVoltage'] / $divisor;
$in_index = '3.1.3.' . $index;
if (substr($index, 0, 1) == 2 && $data['upsPhaseInputVoltage'] != -1) {
$descr = 'Phase ' . substr($index, -1) . ' Bypass Input';
discover_sensor($valid['sensor'], 'voltage', $device, $voltage_oid, $in_index, $type, $descr, $divisor, 0, null, null, null, null, $voltage);
} elseif (substr($index, 0, 1) == 1) {
$descr = 'Phase ' . substr($index, -1) . ' Input';
discover_sensor($valid['sensor'], 'voltage', $device, $voltage_oid, $in_index, $type, $descr, $divisor, 0, null, null, null, null, $voltage);
}
}
} else {
$oids = snmp_walk($device, '.1.3.6.1.4.1.318.1.1.8.5.3.3.1.3', '-OsqnU');
d_echo($oids . "\n");
if ($oids) {
echo 'APC In ';
$divisor = 1;
$type = 'apc';
foreach (explode("\n", $oids) as $data) {
$data = trim($data);
if ($data) {
[$oid, $current] = explode(' ', $data, 2);
$split_oid = explode('.', $oid);
$index = $split_oid[count($split_oid) - 3];
$oid = '.1.3.6.1.4.1.318.1.1.8.5.3.3.1.3.' . $index . '.1.1';
$descr = 'Input Feed ' . chr(64 + $index);
discover_sensor($valid['sensor'], 'voltage', $device, $oid, "3.3.1.3.$index", $type, $descr, $divisor, '1', null, null, null, null, $current);
}
}
}
$oids = snmp_walk($device, '.1.3.6.1.4.1.318.1.1.8.5.4.3.1.3', '-OsqnU');
d_echo($oids . "\n");
if ($oids) {
echo ' APC Out ';
$divisor = 1;
$type = 'apc';
foreach (explode("\n", $oids) as $data) {
$data = trim($data);
if ($data) {
[$oid, $current] = explode(' ', $data, 2);
$split_oid = explode('.', $oid);
$index = $split_oid[count($split_oid) - 3];
$oid = '.1.3.6.1.4.1.318.1.1.8.5.4.3.1.3.' . $index . '.1.1';
$descr = 'Output Feed';
if (count(explode("\n", $oids)) > 1) {
$descr .= " $index";
}
discover_sensor($valid['sensor'], 'voltage', $device, $oid, "4.3.1.3.$index", $type, $descr, $divisor, '1', null, null, null, null, $current);
}
}
}
// upsHighPrecInputLineVoltage
$oids = snmp_get($device, '.1.3.6.1.4.1.318.1.1.1.3.3.1.0', '-OsqnU');
d_echo($oids . "\n");
$divisor = 10;
$index = '3.3.1.0';
if (! $oids) {
// upsAdvInputLineVoltage, used in case high precision is not available
$oids = snmp_get($device, '.1.3.6.1.4.1.318.1.1.1.3.2.1.0', '-OsqnU', '');
d_echo($oids . "\n");
$divisor = 1;
$index = '3.2.1.0';
}
if ($oids) {
echo ' APC In ';
[$oid,$current] = explode(' ', $oids);
$type = 'apc';
$descr = 'Input';
discover_sensor($valid['sensor'], 'voltage', $device, $oid, $index, $type, $descr, $divisor, '1', null, null, null, null, $current / $divisor);
}
// upsHighPrecOutputVoltage
$oids = snmp_get($device, '.1.3.6.1.4.1.318.1.1.1.4.3.1.0', '-OsqnU');
d_echo($oids . "\n");
$divisor = 10;
$index = '4.3.1.0';
if (! $oids) {
// upsAdvOutputVoltage, used in case high precision is not available
$oids = snmp_get($device, '.1.3.6.1.4.1.318.1.1.1.4.2.1.0', '-OsqnU', '');
d_echo($oids . "\n");
$divisor = 1;
$index = '4.2.1.0';
}
if ($oids) {
echo ' APC Out ';
[$oid,$current] = explode(' ', $oids);
$type = 'apc';
$descr = 'Output';
discover_sensor($valid['sensor'], 'voltage', $device, $oid, $index, $type, $descr, $divisor, '1', null, null, null, null, $current / $divisor);
}
// rPDUIdentDeviceLinetoLineVoltage
$oids = snmp_get($device, '.1.3.6.1.4.1.318.1.1.12.1.15.0', '-OsqnU');
d_echo($oids . "\n");
if ($oids) {
echo ' Voltage In ';
[$oid,$current] = explode(' ', $oids);
if ($current >= 0) { // Newer units using rPDU2 can return the following rPDUIdentDeviceLinetoLineVoltage.0; Value (Integer): -1 hence this check.
$divisor = 1;
$type = 'apc';
$index = '1';
$descr = 'Input';
discover_sensor($valid['sensor'], 'voltage', $device, $oid, $index, $type, $descr, $divisor, '1', null, null, null, null, $current);
}
}
// rPDU2PhaseStatusVoltage
$oids = snmp_walk($device, '.1.3.6.1.4.1.318.1.1.26.6.3.1.6', '-OsqnU');
d_echo($oids . "\n");
if ($oids) {
echo ' Voltage In ';
[$oid,$current] = explode(' ', $oids);
if ($current >= 0) { // Some units using rPDU2 can return rPDU2PhaseStatusVoltage.1; Value (Integer): -1 hence this check. Example : AP7900B
$divisor = 1;
$type = 'apc';
$index = '1';
$descr = 'Input';
discover_sensor($valid['sensor'], 'voltage', $device, $oid, $index, $type, $descr, $divisor, '1', null, null, null, null, $current);
}
}
}