static
void DoEvent(
SaHpiSessionIdT sessionid,
SaHpiResourceIdT resourceid,
SaHpiSensorRecT *sensorrec )
{
SaHpiSensorNumT sensornum;
SaHpiSensorReadingT reading;
SaHpiSensorReadingT conv_reading;
SaHpiSensorThresholdsT senstbuff1;
SaHpiSensorThresholdsT senstbuff2;
SaHpiTimeoutT timeout = (SaHpiInt64T)(12 * HPI_NSEC_PER_SEC); /* 12 seconds */
SaHpiEventT event;
SaHpiRptEntryT rptentry;
SaHpiRdrT rdr;
char *unit;
int eventflag = 0;
int i;
sensornum = sensorrec->Num;
/* Get current sensor reading */
rv = saHpiSensorReadingGet( sessionid, resourceid, sensornum, &reading);
if (rv != SA_OK) {
printf( "\n");
/* printf("ReadingGet ret=%d\n", rv); */
return;
}
if ((reading.ValuesPresent & SAHPI_SRF_INTERPRETED) == 0 &&
(reading.ValuesPresent & SAHPI_SRF_RAW)) {
/* only try convert if intrepreted not available. */
rv = saHpiSensorReadingConvert(sessionid, resourceid, sensornum,
&reading, &conv_reading);
if (rv != SA_OK) {
printf("raw=%x conv_ret=%d\n", reading.Raw, rv);
/* printf("conv_rv=%s\n", decode_error(rv)); */
return;
} else {
reading.Interpreted.Type = conv_reading.Interpreted.Type;
reading.Interpreted.Value.SensorUint32 =
conv_reading.Interpreted.Value.SensorUint32;
}
}
/* Determine units of interpreted reading */
i = sensorrec->DataFormat.BaseUnits;
if (i > NSU) i = 0;
unit = units[i];
printf(" = %05.2f %s \n",
reading.Interpreted.Value.SensorFloat32, unit);
/* Retrieve current threshold setings, twice */
/* once for backup and once for modification */
/* Get backup copy */
rv = saHpiSensorThresholdsGet(
sessionid, resourceid, sensornum, &senstbuff1);
if (rv != SA_OK) return;
/* Get modification copy */
rv = saHpiSensorThresholdsGet(
sessionid, resourceid, sensornum, &senstbuff2);
if (rv != SA_OK) return;
/* Display current thresholds */
if (rv == SA_OK) {
printf( " Current\n");
ShowThresh( &senstbuff2 );
}
/* Set new threshold to current reading + 10% */
senstbuff2.LowMajor.Interpreted.Value.SensorFloat32 =
reading.Interpreted.Value.SensorFloat32 * (SaHpiFloat32T)1.10;
printf( "ValuesPresent = %x\n", senstbuff2.LowMajor.ValuesPresent);
printf( "Values Mask = %x\n", (SAHPI_SRF_RAW));
senstbuff2.LowMajor.ValuesPresent =
senstbuff2.LowMajor.ValuesPresent ^ (SAHPI_SRF_RAW);
printf( "ValuesPresent = %x\n", senstbuff2.LowMajor.ValuesPresent);
/* Display new current thresholds */
if (rv == SA_OK) {
printf( " New\n");
ShowThresh( &senstbuff2 );
}
/* See what Events are Enabled */
rv = saHpiSensorEventEnablesGet(
sessionid, resourceid, sensornum, &enables1);
if (rv != SA_OK) return;
printf( "Sensor Event Enables: \n");
printf( " Sensor Status = %x\n", enables1.SensorStatus);
printf( " Assert Events = %x\n", enables1.AssertEvents);
printf( " Deassert Events = %x\n", enables1.DeassertEvents);
/*
enables1.AssertEvents = 0x0400;
enables1.DeassertEvents = 0x0400;
rv = saHpiSensorEventEnablesSet(
sessionid, resourceid, sensornum, &enables1);
if (rv != SA_OK) return;
*/
/************************
Temporary exit */
/*
return;
*/
/* Subscribe to New Events, only */
printf( "Subscribe to events\n");
rv = saHpiSubscribe( sessionid, (SaHpiBoolT)0 );
if (rv != SA_OK) return;
/* Set new thresholds */
printf( "Set new thresholds\n");
rv = saHpiSensorThresholdsSet(
sessionid, resourceid, sensornum, &senstbuff2);
if (rv != SA_OK) return;
/* Go wait on event to occur */
printf( "Go and get the event\n");
eventflag = 0;
while ( eventflag == 0) {
rv = saHpiEventGet( sessionid, timeout, &event, &rdr, &rptentry );
if (rv != SA_OK) {
if (rv != SA_ERR_HPI_TIMEOUT) {
printf( "Error during EventGet - Test FAILED\n");
return;
} else {
printf( "Time expired during EventGet - Test FAILED\n");
/* Reset to the original thresholds */
printf( "Reset thresholds\n");
rv = saHpiSensorThresholdsSet(
sessionid, resourceid, sensornum, &senstbuff1);
if (rv != SA_OK) return;
/* Re-read threshold values */
rv = saHpiSensorThresholdsGet(
sessionid, resourceid, sensornum, &senstbuff2);
if (rv != SA_OK) return;
return;
}
}
/* Decode the event information */
printf( "Decode event info\n");
if (event.EventType == SAHPI_ET_SENSOR) {
printf( "Sensor # = %2d Severity = %2x\n",
event.EventDataUnion.SensorEvent.SensorNum, event.Severity );
if (event.EventDataUnion.SensorEvent.SensorNum == sensornum) {
eventflag = 1;
printf( "Got it - Test PASSED\n");
}
}
}
/* Reset to the original thresholds */
printf( "Reset thresholds\n");
rv = saHpiSensorThresholdsSet(
sessionid, resourceid, sensornum, &senstbuff1);
if (rv != SA_OK) return;
/* Re-read threshold values */
rv = saHpiSensorThresholdsGet(
sessionid, resourceid, sensornum, &senstbuff2);
if (rv != SA_OK) return;
/* Display reset thresholds */
if (rv == SA_OK) {
printf( " Reset\n");
ShowThresh( &senstbuff2 );
}
/* Unsubscribe to future events */
printf( "Unsubscribe\n");
rv = saHpiUnsubscribe( sessionid );
return;
} /*end DoEvent*/
cOpenHpiDaemon::tResult
cOpenHpiDaemon::HandleMsg( cConnection *c,
const cMessageHeader &header, const void *data,
cMessageHeader &rh, void *&rd )
{
cHpiMarshal *hm = HpiMarshalFind( header.m_id );
// check for function and data length
if ( !hm || hm->m_request_len < header.m_len )
{
//MessageHeaderInit( &rh, eMhError, header.m_seq, 0, 0 );
//rd = 0;
fprintf( stderr, "wrong message length: id %d !\n", header.m_id );
return eResultError;
}
assert( hm->m_reply_len );
// init reply header
MessageHeaderInit( &rh, eMhReply, header.m_seq, header.m_id, hm->m_reply_len );
// alloc reply buffer
rd = calloc( 1, hm->m_reply_len );
SaErrorT ret;
switch( header.m_id )
{
case eFsaHpiSessionOpen:
{
SaHpiDomainIdT domain_id;
SaHpiSessionIdT session_id = 0;
HpiDemarshalRequest1( header.m_flags & dMhEndianBit, hm, data, (void *)&domain_id );
ret = saHpiSessionOpen( domain_id, &session_id, 0 );
DbgFunc( "saHpiSessionOpen( %x, %x ) = %d\n",
domain_id, session_id, ret );
if ( ret == SA_OK )
c->AddSession( session_id );
rh.m_len = HpiMarshalReply1( hm, rd, &ret, &session_id );
}
break;
case eFsaHpiSessionClose:
{
SaHpiSessionIdT session_id;
HpiDemarshalRequest1( header.m_flags & dMhEndianBit, hm, data, &session_id );
ret = saHpiSessionClose( session_id );
DbgFunc( "saHpiSessionClose( %x ) = %d\n", session_id, ret );
if ( ret == SA_OK )
c->RemSession( session_id );
rh.m_len = HpiMarshalReply0( hm, rd, &ret );
}
break;
case eFsaHpiResourcesDiscover:
{
SaHpiSessionIdT session_id;
HpiDemarshalRequest1( header.m_flags & dMhEndianBit, hm, data, &session_id );
ret = saHpiResourcesDiscover( session_id );
DbgFunc( "saHpiResourcesDiscover( %x ) = %d\n", session_id, ret );
rh.m_len = HpiMarshalReply0( hm, rd, &ret );
}
break;
case eFsaHpiRptInfoGet:
{
SaHpiSessionIdT session_id;
SaHpiRptInfoT rpt_info;
HpiDemarshalRequest1( header.m_flags & dMhEndianBit, hm, data, &session_id );
ret = saHpiRptInfoGet( session_id, &rpt_info );
DbgFunc( "saHpiRptInfoGet( %x ) = %d\n", session_id, ret );
rh.m_len = HpiMarshalReply1( hm, rd, &ret, &rpt_info );
}
break;
case eFsaHpiRptEntryGet:
{
SaHpiSessionIdT session_id;
SaHpiEntryIdT entry_id;
SaHpiEntryIdT next_entry_id;
SaHpiRptEntryT rpt_entry;
HpiDemarshalRequest2( header.m_flags & dMhEndianBit, hm, data,
&session_id, &entry_id );
ret = saHpiRptEntryGet( session_id, entry_id, &next_entry_id, &rpt_entry );
DbgFunc( "saHpiRptEntryGet( %x, %x, %x ) = %d\n",
session_id, entry_id, next_entry_id, ret );
rh.m_len = HpiMarshalReply2( hm, rd, &ret, &next_entry_id, &rpt_entry );
}
break;
case eFsaHpiRptEntryGetByResourceId:
{
SaHpiSessionIdT session_id;
SaHpiResourceIdT resource_id;
SaHpiRptEntryT rpt_entry;
HpiDemarshalRequest2( header.m_flags & dMhEndianBit, hm, data,
&session_id, &resource_id );
ret = saHpiRptEntryGetByResourceId( session_id, resource_id, &rpt_entry );
DbgFunc( "saHpiRptEntryGetByResourceId( %x, %x ) = %d\n",
session_id, resource_id, ret );
rh.m_len = HpiMarshalReply1( hm, rd, &ret, &rpt_entry );
}
break;
case eFsaHpiResourceSeveritySet:
{
SaHpiSessionIdT session_id;
SaHpiResourceIdT resource_id;
SaHpiSeverityT severity;
HpiDemarshalRequest3( header.m_flags & dMhEndianBit, hm, data,
&session_id, &resource_id, &severity );
ret = saHpiResourceSeveritySet( session_id,
resource_id, severity );
DbgFunc( "saHpiResourceSeveritySet( %x, %x ) = %d\n",
session_id, resource_id, ret );
rh.m_len = HpiMarshalReply0( hm, rd, &ret );
}
break;
case eFsaHpiResourceTagSet:
{
SaHpiSessionIdT session_id;
SaHpiResourceIdT resource_id;
SaHpiTextBufferT resource_tag;
HpiDemarshalRequest3( header.m_flags & dMhEndianBit, hm, data,
&session_id, &resource_id, &resource_tag );
ret = saHpiResourceTagSet( session_id, resource_id,
&resource_tag );
DbgFunc( "saHpiResourceTagSet( %x, %x ) = %d\n",
session_id, resource_id, ret );
rh.m_len = HpiMarshalReply0( hm, rd, &ret );
}
break;
case eFsaHpiResourceIdGet:
{
SaHpiSessionIdT session_id;
SaHpiResourceIdT resource_id = 0;
HpiDemarshalRequest1( header.m_flags & dMhEndianBit, hm, data,
&session_id );
ret = saHpiResourceIdGet( session_id, &resource_id );
DbgFunc( "saHpiResourceIdGet( %x ) = %d, %x\n",
session_id, ret, resource_id );
rh.m_len = HpiMarshalReply1( hm, rd, &ret, &resource_id );
}
break;
case eFsaHpiEntitySchemaGet:
{
SaHpiSessionIdT session_id;
SaHpiUint32T schema_id = 0;
HpiDemarshalRequest1( header.m_flags & dMhEndianBit, hm, data,
&session_id );
ret = saHpiEntitySchemaGet( session_id, &schema_id );
DbgFunc( "saHpiEntitySchemaGet( %x ) = %d, %x\n",
session_id, ret, schema_id );
rh.m_len = HpiMarshalReply1( hm, rd, &ret, &schema_id );
}
break;
case eFsaHpiEventLogInfoGet:
{
SaHpiSessionIdT session_id;
SaHpiResourceIdT resource_id;
SaHpiSelInfoT info;
HpiDemarshalRequest2( header.m_flags & dMhEndianBit, hm, data,
&session_id, &resource_id );
ret = saHpiEventLogInfoGet( session_id, resource_id, &info );
DbgFunc( "saHpiEventLogInfoGet( %x, %x ) = %d\n",
session_id, resource_id, ret );
rh.m_len = HpiMarshalReply1( hm, rd, &ret, &info );
}
break;
case eFsaHpiEventLogEntryGet:
{
SaHpiSessionIdT session_id;
SaHpiResourceIdT resource_id;
SaHpiSelEntryIdT entry_id;
SaHpiSelEntryIdT prev_entry_id = 0;
SaHpiSelEntryIdT next_entry_id = 0;
SaHpiSelEntryT event_log_entry;
SaHpiRdrT rdr;
SaHpiRptEntryT rpt_entry;
memset( &rdr, 0, sizeof( SaHpiRdrT ) );
memset( &rpt_entry, 0, sizeof( SaHpiRptEntryT ) );
HpiDemarshalRequest3( header.m_flags & dMhEndianBit, hm, data,
&session_id, &resource_id, &entry_id );
ret = saHpiEventLogEntryGet( session_id, resource_id, entry_id,
&prev_entry_id, &next_entry_id,
&event_log_entry, &rdr, &rpt_entry );
DbgFunc( "saHpiEventLogEntryGet( %x, %x, %x ) = %d\n",
session_id, resource_id, entry_id, ret );
rh.m_len = HpiMarshalReply5( hm, rd, &ret, &prev_entry_id, &next_entry_id,
&event_log_entry, &rdr, &rpt_entry );
}
break;
case eFsaHpiEventLogEntryAdd:
{
SaHpiSessionIdT session_id;
SaHpiResourceIdT resource_id;
SaHpiSelEntryT evt_entry;
HpiDemarshalRequest3( header.m_flags & dMhEndianBit, hm, data,
&session_id, &resource_id, &evt_entry );
ret = saHpiEventLogEntryAdd( session_id, resource_id,
&evt_entry );
DbgFunc( "saHpiEventLogEntryAdd( %x, %x ) = %d\n",
session_id, resource_id, ret );
rh.m_len = HpiMarshalReply0( hm, rd, &ret );
}
break;
case eFsaHpiEventLogEntryDelete:
{
SaHpiSessionIdT session_id;
SaHpiResourceIdT resource_id;
SaHpiSelEntryIdT entry_id;
HpiDemarshalRequest3( header.m_flags & dMhEndianBit, hm, data,
&session_id, &resource_id, &entry_id );
ret = saHpiEventLogEntryDelete( session_id, resource_id, entry_id );
DbgFunc( "saHpiEventLogEntryDelete( %x, %x, %x ) = %d\n",
session_id, resource_id, entry_id, ret );
rh.m_len = HpiMarshalReply0( hm, rd, &ret );
}
break;
case eFsaHpiEventLogClear:
{
SaHpiSessionIdT session_id;
SaHpiResourceIdT resource_id;
HpiDemarshalRequest2( header.m_flags & dMhEndianBit, hm, data,
&session_id, &resource_id );
ret = saHpiEventLogClear( session_id, resource_id );
DbgFunc( "saHpiEventLogClear( %x, %x ) = %d\n",
session_id, resource_id, ret );
rh.m_len = HpiMarshalReply0( hm, rd, &ret );
}
break;
case eFsaHpiEventLogTimeGet:
{
SaHpiSessionIdT session_id;
SaHpiResourceIdT resource_id;
SaHpiTimeT ti;
HpiDemarshalRequest2( header.m_flags & dMhEndianBit, hm, data,
&session_id, &resource_id );
ret = saHpiEventLogTimeGet( session_id, resource_id, &ti );
DbgFunc( "saHpiEventLogTimeGet( %x, %x ) = %d\n",
session_id, resource_id, ret );
rh.m_len = HpiMarshalReply1( hm, rd, &ret, &ti );
}
break;
case eFsaHpiEventLogTimeSet:
{
SaHpiSessionIdT session_id;
SaHpiResourceIdT resource_id;
SaHpiTimeT ti;
HpiDemarshalRequest3( header.m_flags & dMhEndianBit, hm, data,
&session_id, &resource_id , &ti );
ret = saHpiEventLogTimeSet( session_id, resource_id, ti );
DbgFunc( "saHpiEventLogTimeSet( %x, %x ) = %d\n",
session_id, resource_id, ret );
rh.m_len = HpiMarshalReply0( hm, rd, &ret );
}
break;
case eFsaHpiEventLogStateGet:
{
SaHpiSessionIdT session_id;
SaHpiResourceIdT resource_id;
SaHpiBoolT enable;
HpiDemarshalRequest2( header.m_flags & dMhEndianBit, hm, data,
&session_id, &resource_id );
ret = saHpiEventLogStateGet( session_id, resource_id, &enable );
DbgFunc( "saHpiEventLogStateGet( %x, %x ) = %d\n",
session_id, resource_id, ret );
rh.m_len = HpiMarshalReply1( hm, rd, &ret, &enable );
}
break;
case eFsaHpiEventLogStateSet:
{
SaHpiSessionIdT session_id;
SaHpiResourceIdT resource_id;
SaHpiBoolT enable;
HpiDemarshalRequest3( header.m_flags & dMhEndianBit, hm, data,
&session_id, &resource_id, &enable );
ret = saHpiEventLogStateSet( session_id, resource_id, enable );
DbgFunc( "saHpiEventLogStateSet( %x, %x, %s ) = %d\n",
session_id, resource_id, enable ? "true" : "false", ret );
rh.m_len = HpiMarshalReply0( hm, rd, &ret );
}
break;
case eFsaHpiSubscribe:
{
SaHpiSessionIdT session_id;
SaHpiBoolT provide_active_alarms;
HpiDemarshalRequest2( header.m_flags & dMhEndianBit, hm, data,
&session_id, &provide_active_alarms );
ret = saHpiSubscribe( session_id, provide_active_alarms );
DbgFunc( "saHpiSubscribe( %x, %s ) = %d\n",
session_id, provide_active_alarms ? "true" : "false",
ret );
rh.m_len = HpiMarshalReply0( hm, rd, &ret );
}
break;
case eFsaHpiUnsubscribe:
{
SaHpiSessionIdT session_id;
HpiDemarshalRequest1( header.m_flags & dMhEndianBit, hm, data,
&session_id );
ret = saHpiUnsubscribe( session_id );
DbgFunc( "saHpiUnsubscribe( %x ) = %d\n",
session_id, ret );
rh.m_len = HpiMarshalReply0( hm, rd, &ret );
}
break;
case eFsaHpiEventGet:
{
SaHpiSessionIdT session_id;
SaHpiTimeoutT timeout;
SaHpiEventT event;
SaHpiRdrT rdr;
SaHpiRptEntryT rpt_entry;
HpiDemarshalRequest2( header.m_flags & dMhEndianBit, hm, data,
&session_id, &timeout );
if ( timeout == 0 )
{
ret = saHpiEventGet( session_id, timeout, &event, &rdr, &rpt_entry );
DbgFunc( "saHpiEventGet( %x ) = %d\n",
session_id, ret );
rh.m_len = HpiMarshalReply3( hm, rd, &ret, &event, &rdr, &rpt_entry );
}
else
{
cSession *s = c->FindSession( session_id );
if ( s && !s->IsEventGet() )
{
s->EventGet( true );
SaHpiTimeT end;
gettimeofday1( &end );
if ( timeout == SAHPI_TIMEOUT_BLOCK )
end += (SaHpiTimeT)10000*1000000000; //set a long time
else
end += timeout;
s->Timeout() = end;
s->Seq() = header.m_seq;
DbgEvent( "saHpiEventGet( %x ): add to event listener.\n",
s->SessionId() );
return eResultOk;
}
// error
ret = SA_ERR_HPI_BUSY;
rh.m_len = HpiMarshalReply3( hm, rd, &ret, &event, &rdr, &rpt_entry );
}
}
break;
case eFsaHpiRdrGet:
{
SaHpiSessionIdT session_id;
SaHpiResourceIdT resource_id;
SaHpiEntryIdT entry_id;
SaHpiEntryIdT next_entry_id;
SaHpiRdrT rdr;
HpiDemarshalRequest3( header.m_flags & dMhEndianBit, hm, data,
&session_id, &resource_id, &entry_id );
ret = saHpiRdrGet( session_id, resource_id, entry_id,
&next_entry_id, &rdr );
DbgFunc( "saHpiRdrGet( %x, %x, %x ) = %d\n",
session_id, resource_id, entry_id, ret );
rh.m_len = HpiMarshalReply2( hm, rd, &ret, &next_entry_id, &rdr );
}
break;
case eFsaHpiSensorReadingGet:
{
SaHpiSessionIdT session_id;
SaHpiResourceIdT resource_id;
SaHpiSensorNumT sensor_num;
SaHpiSensorReadingT reading;
HpiDemarshalRequest3( header.m_flags & dMhEndianBit, hm, data,
&session_id, &resource_id, &sensor_num );
ret = saHpiSensorReadingGet( session_id, resource_id,
sensor_num, &reading );
DbgFunc( "saHpiSensorReadingGet( %x, %x, %x ) = %d\n",
session_id, resource_id, sensor_num, ret );
rh.m_len = HpiMarshalReply1( hm, rd, &ret, &reading );
}
break;
case eFsaHpiSensorReadingConvert:
{
SaHpiSessionIdT session_id;
SaHpiResourceIdT resource_id;
SaHpiSensorNumT sensor_num;
SaHpiSensorReadingT reading_input;
SaHpiSensorReadingT converted_reading;
HpiDemarshalRequest4( header.m_flags & dMhEndianBit, hm, data,
&session_id, &resource_id, &sensor_num,
&reading_input );
ret = saHpiSensorReadingConvert( session_id,
resource_id, sensor_num,
&reading_input,
&converted_reading );
DbgFunc( "saHpiSensorReadingConvert( %x, %x, %x ) = %d\n",
session_id, resource_id, sensor_num, ret );
rh.m_len = HpiMarshalReply1( hm, rd, &ret, &converted_reading );
}
break;
case eFsaHpiSensorThresholdsGet:
{
SaHpiSessionIdT session_id;
SaHpiResourceIdT resource_id;
SaHpiSensorNumT sensor_num;
SaHpiSensorThresholdsT sensor_thresholds;
HpiDemarshalRequest3( header.m_flags & dMhEndianBit, hm, data,
&session_id, &resource_id, &sensor_num );
ret = saHpiSensorThresholdsGet( session_id,
resource_id, sensor_num,
&sensor_thresholds);
DbgFunc( "saHpiSensorThresholdsGet( %x, %x, %x ) = %d\n",
session_id, resource_id, sensor_num, ret );
rh.m_len = HpiMarshalReply1( hm, rd, &ret, &sensor_thresholds );
}
break;
case eFsaHpiSensorThresholdsSet:
{
SaHpiSessionIdT session_id;
SaHpiResourceIdT resource_id;
SaHpiSensorNumT sensor_num;
SaHpiSensorThresholdsT sensor_thresholds;
HpiDemarshalRequest4( header.m_flags & dMhEndianBit, hm, data,
&session_id, &resource_id, &sensor_num,
&sensor_thresholds );
ret = saHpiSensorThresholdsSet( session_id, resource_id,
sensor_num,
&sensor_thresholds );
DbgFunc( "saHpiSensorThresholdsSet( %x, %x, %x ) = %d\n",
session_id, resource_id, sensor_num, ret );
rh.m_len = HpiMarshalReply0( hm, rd, &ret );
}
break;
case eFsaHpiSensorTypeGet:
{
SaHpiResourceIdT resource_id;
SaHpiSessionIdT session_id;
SaHpiSensorNumT sensor_num;
SaHpiSensorTypeT type;
SaHpiEventCategoryT category;
HpiDemarshalRequest3( header.m_flags & dMhEndianBit, hm, data,
&session_id, &resource_id, &sensor_num );
ret = saHpiSensorTypeGet( session_id, resource_id,
sensor_num, &type, &category );
DbgFunc( "saHpiSensorTypeGet( %x, %x, %x ) = %d\n",
session_id, resource_id, sensor_num, ret );
rh.m_len = HpiMarshalReply2( hm, rd, &ret, &type, &category );
}
break;
case eFsaHpiSensorEventEnablesGet:
{
SaHpiSessionIdT session_id;
SaHpiResourceIdT resource_id;
SaHpiSensorNumT sensor_num;
SaHpiSensorEvtEnablesT enables;
HpiDemarshalRequest3( header.m_flags & dMhEndianBit, hm, data,
&session_id, &resource_id, &sensor_num );
ret = saHpiSensorEventEnablesGet( session_id, resource_id,
sensor_num, &enables );
DbgFunc( "saHpiSensorEventEnablesGet( %x, %x, %x ) = %d\n",
session_id, resource_id, sensor_num, ret );
rh.m_len = HpiMarshalReply1( hm, rd, &ret, &enables );
}
break;
case eFsaHpiSensorEventEnablesSet:
{
SaHpiSessionIdT session_id;
SaHpiResourceIdT resource_id;
SaHpiSensorNumT sensor_num;
SaHpiSensorEvtEnablesT enables;
HpiDemarshalRequest4( header.m_flags & dMhEndianBit, hm, data,
&session_id, &resource_id, &sensor_num,
&enables );
ret = saHpiSensorEventEnablesSet( session_id, resource_id,
sensor_num, &enables );
DbgFunc( "saHpiSensorEventEnablesSet( %x, %x, %x ) = %d\n",
session_id, resource_id, sensor_num, ret );
rh.m_len = HpiMarshalReply0( hm, rd, &ret );
}
break;
case eFsaHpiControlTypeGet:
{
SaHpiSessionIdT session_id;
SaHpiResourceIdT resource_id;
SaHpiCtrlNumT ctrl_num;
SaHpiCtrlTypeT type;
HpiDemarshalRequest3( header.m_flags & dMhEndianBit, hm, data,
&session_id, &resource_id, &ctrl_num );
ret = saHpiControlTypeGet( session_id, resource_id, ctrl_num,
&type );
DbgFunc( "saHpiControlTypeGet( %x, %x, %x ) = %d\n",
session_id, resource_id, ctrl_num, ret );
rh.m_len = HpiMarshalReply1( hm, rd, &ret, &type );
}
break;
case eFsaHpiControlStateGet:
{
SaHpiSessionIdT session_id;
SaHpiResourceIdT resource_id;
SaHpiCtrlNumT ctrl_num;
SaHpiCtrlStateT ctrl_state;
HpiDemarshalRequest3( header.m_flags & dMhEndianBit, hm, data,
&session_id, &resource_id, &ctrl_num );
ret = saHpiControlStateGet( session_id, resource_id,
ctrl_num, &ctrl_state );
DbgFunc( "saHpiControlStateGet( %x, %x, %x ) = %d\n",
session_id, resource_id, ctrl_num, ret );
rh.m_len = HpiMarshalReply1( hm, rd, &ret, &ctrl_state );
}
break;
case eFsaHpiControlStateSet:
{
SaHpiSessionIdT session_id;
SaHpiResourceIdT resource_id;
SaHpiCtrlNumT ctrl_num;
SaHpiCtrlStateT ctrl_state;
HpiDemarshalRequest4( header.m_flags & dMhEndianBit, hm, data,
&session_id, &resource_id, &ctrl_num,
&ctrl_state );
ret = saHpiControlStateSet( session_id, resource_id,
ctrl_num, &ctrl_state );
DbgFunc( "saHpiControlStateSet( %x, %x, %x ) = %d\n",
session_id, resource_id, ctrl_num, ret );
rh.m_len = HpiMarshalReply0( hm, rd, &ret );
}
break;
case eFsaHpiEntityInventoryDataRead:
{
SaHpiSessionIdT session_id;
SaHpiResourceIdT resource_id;
SaHpiEirIdT eir_id;
SaHpiUint32T buffer_size;
unsigned char *buffer = 0;
SaHpiUint32T actual_size;
HpiDemarshalRequest4( header.m_flags & dMhEndianBit, hm, data,
&session_id, &resource_id, &eir_id, &buffer_size );
if ( buffer_size )
buffer = new unsigned char [buffer_size];
ret = saHpiEntityInventoryDataRead( session_id, resource_id, eir_id,
buffer_size, (SaHpiInventoryDataT *)(void *)buffer,
&actual_size );
DbgFunc( "saHpintityInventoryDataRead( %x, %x, %x, %d ) = %d\n",
session_id, resource_id, eir_id, buffer_size, ret );
const cMarshalType *reply[4];
reply[0] = &SaErrorType; // SA_OK
reply[1] = &SaHpiUint32Type; // actual size
const void *params[3];
params[0] = &ret;
params[1] = &actual_size;
if ( ret != SA_OK || buffer == 0 )
reply[2] = 0;
else
{
reply[2] = &SaHpiInventoryDataType, // inventory data
reply[3] = 0;
params[2] = buffer;
}
rh.m_len = MarshalArray( reply, params, rd );
if ( buffer )
delete [] buffer;
}
break;
case eFsaHpiEntityInventoryDataWrite:
{
SaHpiSessionIdT session_id;
SaHpiResourceIdT resource_id;
SaHpiEirIdT eir_id;
unsigned char buffer[10240];
HpiDemarshalRequest4( header.m_flags & dMhEndianBit, hm, data,
&session_id, &resource_id, &eir_id, buffer );
ret = saHpiEntityInventoryDataWrite( session_id, resource_id, eir_id,
(SaHpiInventoryDataT *)(void *)buffer );
DbgFunc( "saHpintityInventoryDataWrite( %x, %x, %x ) = %d\n",
session_id, resource_id, eir_id, ret );
rh.m_len = HpiMarshalReply0( hm, rd, &ret );
}
break;
case eFsaHpiWatchdogTimerGet:
{
SaHpiSessionIdT session_id;
SaHpiResourceIdT resource_id;
SaHpiWatchdogNumT watchdog_num;
SaHpiWatchdogT watchdog;
HpiDemarshalRequest3( header.m_flags & dMhEndianBit, hm, data,
&session_id, &resource_id, &watchdog_num );
ret = saHpiWatchdogTimerGet( session_id, resource_id,
watchdog_num, &watchdog );
DbgFunc( "saHpiWatchdogTimerGet( %x, %x, %x ) = %d\n",
session_id, resource_id, watchdog_num, ret );
rh.m_len = HpiMarshalReply1( hm, rd, &ret, &watchdog );
}
break;
case eFsaHpiWatchdogTimerSet:
{
SaHpiSessionIdT session_id;
SaHpiResourceIdT resource_id;
SaHpiWatchdogNumT watchdog_num;
SaHpiWatchdogT watchdog;
HpiDemarshalRequest4( header.m_flags & dMhEndianBit, hm, data,
&session_id, &resource_id, &watchdog_num,
&watchdog );
ret = saHpiWatchdogTimerSet( session_id, resource_id,
watchdog_num, &watchdog );
DbgFunc( "saHpiWatchdogTimerSet( %x, %x, %x ) = %d\n",
session_id, resource_id, watchdog_num, ret );
rh.m_len = HpiMarshalReply0( hm, rd, &ret );
}
break;
case eFsaHpiWatchdogTimerReset:
{
SaHpiSessionIdT session_id;
SaHpiResourceIdT resource_id;
SaHpiWatchdogNumT watchdog_num;
HpiDemarshalRequest3( header.m_flags & dMhEndianBit, hm, data,
&session_id, &resource_id, &watchdog_num );
ret = saHpiWatchdogTimerReset( session_id, resource_id,
watchdog_num );
DbgFunc( "eFsaHpiWatchdogTimerReset( %x, %x, %x ) = %d\n",
session_id, resource_id, watchdog_num, ret );
rh.m_len = HpiMarshalReply0( hm, rd, &ret );
}
break;
case eFsaHpiHotSwapControlRequest:
{
SaHpiSessionIdT session_id;
SaHpiResourceIdT resource_id;
HpiDemarshalRequest2( header.m_flags & dMhEndianBit, hm, data,
&session_id, &resource_id );
ret = saHpiHotSwapControlRequest( session_id, resource_id );
DbgFunc( "saHpiHotSwapControlRequest( %x, %x ) = %d\n",
session_id, resource_id , ret );
rh.m_len = HpiMarshalReply0( hm, rd, &ret );
}
break;
case eFsaHpiResourceActiveSet:
{
SaHpiSessionIdT session_id;
SaHpiResourceIdT resource_id;
HpiDemarshalRequest2( header.m_flags & dMhEndianBit, hm, data,
&session_id, &resource_id );
ret = saHpiResourceActiveSet( session_id, resource_id );
DbgFunc( "saHpiResourceActiveSet( %x, %x ) = %d\n",
session_id, resource_id , ret );
rh.m_len = HpiMarshalReply0( hm, rd, &ret );
}
break;
case eFsaHpiResourceInactiveSet:
{
SaHpiSessionIdT session_id;
SaHpiResourceIdT resource_id;
HpiDemarshalRequest2( header.m_flags & dMhEndianBit, hm, data,
&session_id, &resource_id );
ret = saHpiResourceInactiveSet( session_id, resource_id );
DbgFunc( "saHpiResourceInactiveSet( %x, %x ) = %d\n",
session_id, resource_id , ret );
rh.m_len = HpiMarshalReply0( hm, rd, &ret );
}
break;
case eFsaHpiAutoInsertTimeoutGet:
{
SaHpiSessionIdT session_id;
SaHpiTimeoutT timeout;
HpiDemarshalRequest1( header.m_flags & dMhEndianBit, hm, data,
&session_id );
ret = saHpiAutoInsertTimeoutGet( session_id, &timeout );
DbgFunc( "saHpiAutoInsertTimeoutGet( %x ) = %d\n",
session_id, ret );
rh.m_len = HpiMarshalReply1( hm, rd, &ret, &timeout );
}
break;
case eFsaHpiAutoInsertTimeoutSet:
{
SaHpiSessionIdT session_id;
SaHpiTimeoutT timeout;
HpiDemarshalRequest2( header.m_flags & dMhEndianBit, hm, data,
&session_id, &timeout );
ret = saHpiAutoInsertTimeoutSet( session_id, timeout );
DbgFunc( "saHpiAutoInsertTimeoutSet( %x ) = %d\n",
session_id, ret );
rh.m_len = HpiMarshalReply0( hm, rd, &ret );
}
break;
case eFsaHpiAutoExtractTimeoutGet:
{
SaHpiSessionIdT session_id;
SaHpiResourceIdT resource_id;
SaHpiTimeoutT timeout;
HpiDemarshalRequest2( header.m_flags & dMhEndianBit, hm, data,
&session_id, &resource_id );
ret = saHpiAutoExtractTimeoutGet( session_id, resource_id, &timeout );
DbgFunc( "saHpiAutoExtractTimeoutGet( %x, %x ) = %d\n",
session_id, resource_id, ret );
rh.m_len = HpiMarshalReply1( hm, rd, &ret, &timeout );
}
break;
case eFsaHpiAutoExtractTimeoutSet:
{
SaHpiSessionIdT session_id;
SaHpiResourceIdT resource_id;
SaHpiTimeoutT timeout;
HpiDemarshalRequest3( header.m_flags & dMhEndianBit, hm, data,
&session_id, &resource_id, &timeout );
ret = saHpiAutoExtractTimeoutSet( session_id, resource_id, timeout );
DbgFunc( "saHpiAutoExtractTimeoutSet( %x, %x ) = %d\n",
session_id, resource_id, ret );
rh.m_len = HpiMarshalReply0( hm, rd, &ret );
}
break;
case eFsaHpiHotSwapStateGet:
{
SaHpiSessionIdT session_id;
SaHpiResourceIdT resource_id;
SaHpiHsStateT state;
HpiDemarshalRequest2( header.m_flags & dMhEndianBit, hm, data,
&session_id, &resource_id );
ret = saHpiHotSwapStateGet( session_id, resource_id, &state );
DbgFunc( "saHpiHotSwapStateGet( %x, %x ) = %d\n",
session_id, resource_id, ret );
rh.m_len = HpiMarshalReply1( hm, rd, &ret, &state );
}
break;
case eFsaHpiHotSwapActionRequest:
{
SaHpiSessionIdT session_id;
SaHpiResourceIdT resource_id;
SaHpiHsActionT action;
HpiDemarshalRequest3( header.m_flags & dMhEndianBit, hm, data,
&session_id, &resource_id, &action );
ret = saHpiHotSwapActionRequest( session_id, resource_id, action );
DbgFunc( "saHpiHotSwapActionRequest( %x, %x ) = %d\n",
session_id, resource_id , ret );
rh.m_len = HpiMarshalReply0( hm, rd, &ret );
}
break;
case eFsaHpiResourcePowerStateGet:
{
SaHpiSessionIdT session_id;
SaHpiResourceIdT resource_id;
SaHpiHsPowerStateT state;
HpiDemarshalRequest2( header.m_flags & dMhEndianBit, hm, data,
&session_id, &resource_id );
ret = saHpiResourcePowerStateGet( session_id, resource_id, &state );
DbgFunc( "saHpiResourcePowerStateGet( %x, %x ) = %d\n",
session_id, resource_id, ret );
rh.m_len = HpiMarshalReply1( hm, rd, &ret, &state );
}
break;
case eFsaHpiResourcePowerStateSet:
{
SaHpiSessionIdT session_id;
SaHpiResourceIdT resource_id;
SaHpiHsPowerStateT state;
HpiDemarshalRequest3( header.m_flags & dMhEndianBit, hm, data,
&session_id, &resource_id, &state );
ret = saHpiResourcePowerStateSet( session_id, resource_id, state );
DbgFunc( "(saHpiResourcePowerStateSet %x, %x ) = %d\n",
session_id, resource_id , ret );
rh.m_len = HpiMarshalReply0( hm, rd, &ret );
}
break;
case eFsaHpiHotSwapIndicatorStateGet:
{
SaHpiSessionIdT session_id;
SaHpiResourceIdT resource_id;
SaHpiHsIndicatorStateT state;
HpiDemarshalRequest2( header.m_flags & dMhEndianBit, hm, data,
&session_id, &resource_id );
ret = saHpiHotSwapIndicatorStateGet( session_id, resource_id, &state );
DbgFunc( "saHpiHotSwapIndicatorStateGet( %x, %x ) = %d\n",
session_id, resource_id , ret );
rh.m_len = HpiMarshalReply1( hm, rd, &ret, &state );
}
break;
case eFsaHpiHotSwapIndicatorStateSet:
{
SaHpiSessionIdT session_id;
SaHpiResourceIdT resource_id;
SaHpiHsIndicatorStateT state;
HpiDemarshalRequest3( header.m_flags & dMhEndianBit, hm, data,
&session_id, &resource_id, &state );
ret = saHpiHotSwapIndicatorStateSet( session_id, resource_id, state );
DbgFunc( "saHpiHotSwapIndicatorStateSet( %x, %x ) = %d\n",
session_id, resource_id , ret );
rh.m_len = HpiMarshalReply0( hm, rd, &ret );
}
break;
case eFsaHpiParmControl:
{
SaHpiSessionIdT session_id;
SaHpiResourceIdT resource_id;
SaHpiParmActionT action;
HpiDemarshalRequest3( header.m_flags & dMhEndianBit, hm, data,
&session_id, &resource_id, &action );
ret = saHpiParmControl( session_id, resource_id, action );
DbgFunc( "saHpiParmControl( %x, %x ) = %d\n",
session_id, resource_id, ret );
rh.m_len = HpiMarshalReply0( hm, rd, &ret );
}
break;
case eFsaHpiResourceResetStateGet:
{
SaHpiSessionIdT session_id;
SaHpiResourceIdT resource_id;
SaHpiResetActionT reset_action;
HpiDemarshalRequest2( header.m_flags & dMhEndianBit, hm, data,
&session_id, &resource_id );
ret = saHpiResourceResetStateGet( session_id, resource_id,
&reset_action );
DbgFunc( "saHpiResourceResetStateGet( %x, %x ) = %d\n",
session_id, resource_id, ret );
rh.m_len = HpiMarshalReply1( hm, rd, &ret, &reset_action );
}
break;
case eFsaHpiResourceResetStateSet:
{
SaHpiSessionIdT session_id;
SaHpiResourceIdT resource_id;
SaHpiResetActionT reset_action;
HpiDemarshalRequest3( header.m_flags & dMhEndianBit, hm, data,
&session_id, &resource_id, &reset_action );
ret = saHpiResourceResetStateSet( session_id, resource_id, reset_action );
DbgFunc( "saHpiResourceResetStateSet( %x, %x ) = %d\n",
session_id, resource_id, ret );
rh.m_len = HpiMarshalReply0( hm, rd, &ret );
}
break;
default:
assert( 0 );
break;
}
assert( rh.m_len <= hm->m_reply_len );
return eResultReply;
}
static void ShowSensor(
SaHpiSessionIdT sessionid,
SaHpiResourceIdT resourceid,
SaHpiSensorRecT *sensorrec )
{
SaHpiSensorNumT sensornum;
SaHpiSensorReadingT reading;
SaHpiSensorReadingT conv_reading;
SaHpiSensorThresholdsT senstbuff;
SaErrorT rv;
char *unit;
int i;
sensornum = sensorrec->Num;
rv = saHpiSensorReadingGet(sessionid,resourceid, sensornum, &reading);
if (rv != SA_OK) {
printf("ReadingGet ret=%d\n", rv);
return;
}
if ((reading.ValuesPresent & SAHPI_SRF_INTERPRETED) == 0) {
if ((reading.ValuesPresent & SAHPI_SRF_RAW) == 0) {
/* no raw or interpreted, so just show event status */
/* This is a Compact Sensor */
if (reading.ValuesPresent & SAHPI_SRF_EVENT_STATE)
printf(" = %x %x\n", reading.EventStatus.SensorStatus,
reading.EventStatus.EventStatus);
else printf(" = no reading\n");
return;
} else {
/* have raw, but not interpreted, so try convert. */
rv = saHpiSensorReadingConvert(sessionid, resourceid, sensornum,
&reading, &conv_reading);
if (rv != SA_OK) {
printf("raw=%x conv_ret=%d\n", reading.Raw, rv);
/* printf("conv_rv=%s\n", decode_error(rv)); */
return;
}
else {
if (fdebug) printf("conv ok: raw=%x conv=%x\n", reading.Raw,
conv_reading.Interpreted.Value.SensorUint32);
reading.Interpreted.Type = conv_reading.Interpreted.Type;
if (reading.Interpreted.Type == SAHPI_SENSOR_INTERPRETED_TYPE_BUFFER)
{
memcpy(reading.Interpreted.Value.SensorBuffer,
conv_reading.Interpreted.Value.SensorBuffer,
4); /* SAHPI_SENSOR_BUFFER_LENGTH); */
/* IPMI 1.5 only returns 4 bytes */
} else
reading.Interpreted.Value.SensorUint32 =
conv_reading.Interpreted.Value.SensorUint32;
}
}
}
/* Also show units of interpreted reading */
i = sensorrec->DataFormat.BaseUnits;
if (i >= NSU) i = 0;
unit = units[i];
switch(reading.Interpreted.Type)
{
case SAHPI_SENSOR_INTERPRETED_TYPE_FLOAT32:
printf(" = %5.2f %s\n",
reading.Interpreted.Value.SensorFloat32,unit);
break;
case SAHPI_SENSOR_INTERPRETED_TYPE_UINT32:
printf(" = %d %s\n",
reading.Interpreted.Value.SensorUint32, unit);
break;
case SAHPI_SENSOR_INTERPRETED_TYPE_BUFFER:
printf(" = %02x %02x %02x %02x\n",
reading.Interpreted.Value.SensorBuffer[0],
reading.Interpreted.Value.SensorBuffer[1],
reading.Interpreted.Value.SensorBuffer[2],
reading.Interpreted.Value.SensorBuffer[3]);
break;
default:
printf(" = %x (itype=%x)\n",
reading.Interpreted.Value.SensorUint32,
reading.Interpreted.Type);
}
if (fshowthr) {
#ifdef SHOWMAX
if ( sensorrec->DataFormat.Range.Flags & SAHPI_SRF_MAX )
printf( " Max of Range: %5.2f\n",
sensorrec->DataFormat.Range.Max.Interpreted.Value.SensorFloat32);
if ( sensorrec->DataFormat.Range.Flags & SAHPI_SRF_MIN )
printf( " Min of Range: %5.2f\n",
sensorrec->DataFormat.Range.Min.Interpreted.Value.SensorFloat32);
#endif
/* Show thresholds, if any */
if ((!sensorrec->Ignore) && (sensorrec->ThresholdDefn.IsThreshold)) {
rv = saHpiSensorThresholdsGet(sessionid, resourceid,
sensornum, &senstbuff);
printf( "\t\t\t");
if ( sensorrec->ThresholdDefn.ReadThold & SAHPI_STM_LOW_MINOR ) {
printf( "LoMin %5.2f ",
senstbuff.LowMinor.Interpreted.Value.SensorFloat32);
}
if ( sensorrec->ThresholdDefn.ReadThold & SAHPI_STM_LOW_MAJOR ) {
printf( "LoMaj %5.2f ",
senstbuff.LowMajor.Interpreted.Value.SensorFloat32);
}
if ( sensorrec->ThresholdDefn.ReadThold & SAHPI_STM_LOW_CRIT ) {
printf( "LoCri %5.2f ",
senstbuff.LowCritical.Interpreted.Value.SensorFloat32);
}
if ( sensorrec->ThresholdDefn.ReadThold & SAHPI_STM_UP_MINOR ) {
printf( "HiMin %5.2f ",
senstbuff.UpMinor.Interpreted.Value.SensorFloat32);
}
if ( sensorrec->ThresholdDefn.ReadThold & SAHPI_STM_UP_MAJOR ) {
printf( "HiMaj %5.2f ",
senstbuff.UpMajor.Interpreted.Value.SensorFloat32);
}
if ( sensorrec->ThresholdDefn.ReadThold & SAHPI_STM_UP_CRIT ) {
printf( "HiCri %5.2f ",
senstbuff.UpCritical.Interpreted.Value.SensorFloat32);
}
#ifdef SHOWMAX
if ( sensorrec->ThresholdDefn.ReadThold & SAHPI_STM_UP_HYSTERESIS ) {
printf( "Hi Hys %5.2f ",
senstbuff.PosThdHysteresis.Interpreted.Value.SensorFloat32);
}
if ( sensorrec->ThresholdDefn.ReadThold & SAHPI_STM_LOW_HYSTERESIS ) {
printf( "Lo Hys %5.2f ",
senstbuff.NegThdHysteresis.Interpreted.Value.SensorFloat32);
}
#endif
printf( "\n");
} /* endif valid threshold */
} /* endif showthr */
return;
} /*end ShowSensor*/
static int sa_show_sensor(
SaHpiResourceIdT resourceid,
SaHpiSensorNumT sensornum )
{
SaHpiSensorReadingT reading;
SaHpiSensorReadingT conv_reading;
SaErrorT rv;
rv = saHpiSensorReadingGet(sessionid,resourceid, sensornum, &reading);
if (rv != SA_OK) {
printf("ReadingGet ret=%d\n", rv);
return rv;
}
if ((reading.ValuesPresent & SAHPI_SRF_INTERPRETED) == 0) {
if ((reading.ValuesPresent & SAHPI_SRF_RAW) == 0) {
/* no raw or interpreted, so just show event status */
/* This is a Compact Sensor */
if (reading.ValuesPresent & SAHPI_SRF_EVENT_STATE)
printf(" = %x %x\n", reading.EventStatus.SensorStatus,
reading.EventStatus.EventStatus);
else printf(" = event-only sensor\n");
return SA_OK;
} else {
/* have raw, but not interpreted, so try convert. */
rv = saHpiSensorReadingConvert(sessionid, resourceid, sensornum,
&reading, &conv_reading);
if (rv != SA_OK) {
printf("raw=%x conv_ret=%d\n", reading.Raw, rv);
/* printf("conv_rv=%s\n", decode_error(rv)); */
return rv;
}
else {
reading.Interpreted.Type = conv_reading.Interpreted.Type;
if (reading.Interpreted.Type == SAHPI_SENSOR_INTERPRETED_TYPE_BUFFER)
{
memcpy(reading.Interpreted.Value.SensorBuffer,
conv_reading.Interpreted.Value.SensorBuffer,
4); /* SAHPI_SENSOR_BUFFER_LENGTH); */
/* IPMI 1.5 only returns 4 bytes */
} else
reading.Interpreted.Value.SensorUint32 =
conv_reading.Interpreted.Value.SensorUint32;
}
}
}
switch(reading.Interpreted.Type)
{
case SAHPI_SENSOR_INTERPRETED_TYPE_FLOAT32:
printf("Value: %5.2f \n",
reading.Interpreted.Value.SensorFloat32);
break;
case SAHPI_SENSOR_INTERPRETED_TYPE_UINT32:
printf("Value: %d \n",
reading.Interpreted.Value.SensorUint32);
break;
case SAHPI_SENSOR_INTERPRETED_TYPE_BUFFER:
printf("Value: %02x %02x %02x %02x\n",
reading.Interpreted.Value.SensorBuffer[0],
reading.Interpreted.Value.SensorBuffer[1],
reading.Interpreted.Value.SensorBuffer[2],
reading.Interpreted.Value.SensorBuffer[3]);
break;
default:
printf("Value: %x (itype=%x)\n",
reading.Interpreted.Value.SensorUint32,
reading.Interpreted.Type);
}
#if 0
printf("Sensor Status: ");
if (reading.EventStatus.SensorStatus & SAHPI_SENSTAT_EVENTS_ENABLED) {
printf("Event Enabled.\n");
} else if (reading.EventStatus.SensorStatus & SAHPI_SENSTAT_SCAN_ENABLED) {
printf("Scan Enabled.\n");
} else if (reading.EventStatus.SensorStatus & SAHPI_SENSTAT_BUSY) {
printf("Busy.\n");
} else {
printf("Unknown.\n");
}
#endif
sa_sen_evt_get(resourceid, sensornum);
sa_get_thres(resourceid, sensornum);
return SA_OK;
}