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|
/* IBM_PROLOG_BEGIN_TAG */
/* This is an automatically generated prolog. */
/* */
/* $Source: src/usr/errl/errlmanager_common.C $ */
/* */
/* OpenPOWER HostBoot Project */
/* */
/* Contributors Listed Below - COPYRIGHT 2015,2017 */
/* [+] International Business Machines Corp. */
/* */
/* */
/* Licensed under the Apache License, Version 2.0 (the "License"); */
/* you may not use this file except in compliance with the License. */
/* You may obtain a copy of the License at */
/* */
/* http://www.apache.org/licenses/LICENSE-2.0 */
/* */
/* Unless required by applicable law or agreed to in writing, software */
/* distributed under the License is distributed on an "AS IS" BASIS, */
/* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or */
/* implied. See the License for the specific language governing */
/* permissions and limitations under the License. */
/* */
/* IBM_PROLOG_END_TAG */
#include <errl/errlmanager.H>
#include <config.h>
#include <hwas/common/hwasCallout.H>
#include <errl/errlreasoncodes.H>
#ifdef CONFIG_BMC_IPMI
#include <ipmi/ipmisel.H>
#include <ipmi/ipmisensor.H>
#include <ipmi/ipmiconfiglookup.H>
#endif
#include <errl/errlentry.H>
#include <sys/mm.h>
#include <pnor/pnorif.H>
#include <errl/errludstring.H>
#include <map>
namespace ERRORLOG
{
extern trace_desc_t* g_trac_errl;
// the maximum number of targets that a callout is associated with
#define MAX_NUM_TARGETS 2
const uint32_t PNOR_ERROR_LENGTH = 4096;
const uint32_t EMPTY_ERRLOG_IN_PNOR = 0xFFFFFFFF;
const uint32_t FIRST_BYTE_ERRLOG = 0xF0000000;
///////////////////////////////////////////////////////////////////////////////
///////////////////////////////////////////////////////////////////////////////
// Global function (not a method on an object) to commit the error log.
void errlCommit(errlHndl_t& io_err, compId_t i_committerComp )
{
ERRORLOG::theErrlManager::instance().commitErrLog(io_err, i_committerComp );
return;
}
///////////////////////////////////////////////////////////////////////////////
// Global function (not a method on an object) to ack that the error log
// was sent to the BMC.
void ErrlManager::errlAckErrorlog(uint32_t i_eid)
{
ERRORLOG::theErrlManager::instance().ackErrLogInPnor(i_eid);
return;
}
///////////////////////////////////////////////////////////////////////////////
// Global function (not a method on an object) to get the hidden logs flag.
uint8_t getHiddenLogsEnable( )
{
return ERRORLOG::theErrlManager::instance().iv_hiddenErrLogsEnable;
}
///////////////////////////////////////////////////////////////////////////////
// Atomically increment log id and return it.
uint32_t ErrlManager::getUniqueErrId()
{
return (__sync_add_and_fetch(&iv_currLogId, 1));
}
// ------------------------------------------------------------------
// setupPnorInfo
// ------------------------------------------------------------------
void ErrlManager::setupPnorInfo()
{
TRACFCOMP( g_trac_errl, ENTER_MRK"setupPnorInfo" );
do
{
// Get HB_ERRLOG PNOR section info from PNOR RP
PNOR::SectionInfo_t info;
errlHndl_t err = PNOR::getSectionInfo( PNOR::HB_ERRLOGS, info );
if (err)
{
TRACFCOMP( g_trac_errl, INFO_MRK"setupPnorInfo getSectionInfo failed");
assert(err == NULL);
break;
}
TRACFCOMP( g_trac_errl, INFO_MRK"setupPnorInfo sectionInfo id %d name \"%s\" size %d",
info.id, info.name, info.size );
#ifndef __HOSTBOOT_RUNTIME
// Set the globals appropriately
iv_pnorAddr = reinterpret_cast<char *> (info.vaddr);
iv_maxErrlInPnor = info.size / PNOR_ERROR_LENGTH;
TRACFCOMP( g_trac_errl, INFO_MRK"setupPnorInfo iv_pnorAddr %p maxErrlInPnor %d",
iv_pnorAddr, iv_maxErrlInPnor );
// initial value, in case PNOR is empty - start at this end slot
// so that our first save will increment and wrap correctly
iv_pnorOpenSlot = (iv_maxErrlInPnor - 1);
// walk thru memory, finding error logs and determine the highest ID
uint32_t l_maxId = 0;
for (uint32_t i = 0; i < iv_maxErrlInPnor; i++)
{
if (!isSlotEmpty(i))
{
uint32_t l_id = readEidFromFlattened(i);
// If eid is not from HB or HBRT (meaning the FSP put this log
// in here for us to 'start' from; FSP eid's aren't in the same
// range as HB/HBRT eid's)
if ( (l_id & FIRST_BYTE_ERRLOG) != ERRLOG_PLID_BASE )
{
// then grab plid instead (FSP will have put a HB plid in
l_id = readPlidFromFlattened(i);
}
// if this is 'my' type of plid (HB or HBRT) see if it's max
if (((l_id & FIRST_BYTE_ERRLOG) == ERRLOG_PLID_BASE ) &&
(l_id > l_maxId ))
{
l_maxId = l_id;
// set this - start at this 'max' slot so that our first
// save will increment correctly
iv_pnorOpenSlot = i;
}
// also check if it's ACKed or not
if (!isSlotACKed(i))
{
TRACFCOMP( g_trac_errl,
INFO_MRK"setupPnorInfo slot %d eid %.8X was not ACKed.",
i, l_id);
#ifdef CONFIG_BMC_IPMI
// for IPMI systems, unflatten to send down to the BMC
err = new ERRORLOG::ErrlEntry(
ERRORLOG::ERRL_SEV_UNRECOVERABLE, 0,0);
char *l_errlAddr = iv_pnorAddr + (PNOR_ERROR_LENGTH * i);
uint64_t rc = err->unflatten(l_errlAddr, PNOR_ERROR_LENGTH);
if (rc != 0)
{
// unflatten didn't work, nothing we can do
TRACFCOMP( g_trac_errl,
ERR_MRK"setupPnorInfo unflatten failed on slot %d eid %.8X.",
i, l_id);
}
else
{
// Decide if we need to skip the error log
setErrlSkipFlag(err);
if(err->getSkipShowingLog())
{
// skip it, go to the next one
continue;
}
if (iv_isIpmiEnabled)
{
// convert to SEL/eSEL and send to BMC over IPMI
sendErrLogToBmc(err,
false /* do not resend SELs */);
delete err;
err = nullptr;
}
else
{
TRACFCOMP( g_trac_errl,
INFO_MRK"setupPnorInfo pushing slot %d eid %.8X to iv_errList.",
i, l_id);
// Pair with IPMI_NOSEL flag to add to the errlList
// so that it'll get sent down when IPMI is up
ErrlFlagPair_t l_pair(err, IPMI_NOSEL_FLAG
#ifdef CONFIG_CONSOLE_OUTPUT_ERRORDISPLAY
| ERRLDISP_FLAG
#endif
);
iv_errlList.push_back(l_pair);
}
}
#else
// for FSP system, this shouldn't ever happen.
setACKInFlattened(i);
#endif
} // not ACKed
} // not empty
} // for
// bump the current eid to 1 past the max eid found
while (!__sync_bool_compare_and_swap(&iv_currLogId, iv_currLogId,
(iv_currLogId & ERRLOG_PLID_BASE_MASK) +
(l_maxId & ERRLOG_PLID_MASK) + 1));
TRACFCOMP( g_trac_errl, INFO_MRK"setupPnorInfo reseting LogId 0x%X", iv_currLogId);
// if error(s) came in before PNOR was ready,
// the error log(s) would be on this list. save now.
ErrlListItr_t it = iv_errlList.begin();
while(it != iv_errlList.end())
{
// Check if PNOR processing is needed
if (_isFlagSet(*it, PNOR_FLAG))
{
//ACK it if no one is there to receive
bool l_savedToPnor = saveErrLogToPnor(it->first);
// check if we actually saved the msg to PNOR
if (l_savedToPnor)
{
// Mark PNOR processing complete
_clearFlag(*it, PNOR_FLAG);
_updateErrlListIter(it);
}
else
{
// still couldn't save it (PNOR maybe full) so
// it's still on the list.
break; // get out of this while loop.
}
}
else
{
++it;
}
}
#endif // __HOSTBOOT_RUNTIME
} while (0);
TRACFCOMP( g_trac_errl, EXIT_MRK"setupPnorInfo");
} // setupPnorInfo
///////////////////////////////////////////////////////////////////////////////
// ErrlManager::incrementPnorOpenSlot()
///////////////////////////////////////////////////////////////////////////////
bool ErrlManager::incrementPnorOpenSlot()
{
uint32_t initialSlot = iv_pnorOpenSlot; // starting slot
do
{
iv_pnorOpenSlot++;
if (iv_pnorOpenSlot == iv_maxErrlInPnor)
{ // wrap
iv_pnorOpenSlot = 0;
}
} while ( !isSlotEmpty(iv_pnorOpenSlot) &&
!isSlotACKed(iv_pnorOpenSlot) &&
(iv_pnorOpenSlot != initialSlot));
// if we got a different slot, return true; else false - no open slots
return (iv_pnorOpenSlot != initialSlot);
} // incrementPnorOpenSlot
///////////////////////////////////////////////////////////////////////////////
// ErrlManager::saveErrLogToPnor()
///////////////////////////////////////////////////////////////////////////////
bool ErrlManager::saveErrLogToPnor( errlHndl_t& io_err)
{
bool rc = false;
TRACFCOMP( g_trac_errl, ENTER_MRK"saveErrLogToPnor eid=%.8x", io_err->eid());
do
{
// Decide whether or not to skip error log
// if so, we'll just 'say' that we saved it and go on.
if( io_err->getSkipShowingLog() )
{
TRACFCOMP( g_trac_errl, INFO_MRK"saveErrLogToPnor: INFORMATIONAL/RECOVERED log, skipping");
rc = true;
break;
}
// save our current slot, and see if there's an open slot
uint32_t l_previousSlot = iv_pnorOpenSlot; // in case flatten fails
if ((iv_pnorAddr != NULL) && incrementPnorOpenSlot())
{
// flatten into PNOR, truncate to the slot size
char *l_pnorAddr =
iv_pnorAddr + (PNOR_ERROR_LENGTH * iv_pnorOpenSlot);
TRACDBIN( g_trac_errl, INFO_MRK"saveErrLogToPnor: l_pnorAddr before",
l_pnorAddr, 128);
uint64_t l_errSize = io_err->flatten(l_pnorAddr,
PNOR_ERROR_LENGTH, true);
if (l_errSize !=0)
{
TRACFCOMP( g_trac_errl, INFO_MRK"saveErrLogToPnor: %d bytes flattened into %p, slot %d",
l_errSize, l_pnorAddr, iv_pnorOpenSlot );
TRACDBIN( g_trac_errl, INFO_MRK"saveErrLogToPnor: l_pnorAddr after",
l_pnorAddr, 128);
// Ensure that this error log is pushed out to PNOR
#ifdef __HOSTBOOT_RUNTIME
PNOR::flush(PNOR::HB_ERRLOGS);
#else
// FLUSH so that only the dirty pages get pushed out
int l_rc = mm_remove_pages(FLUSH,
(void *) l_pnorAddr, l_errSize);
if( l_rc )
{
//If mm_remove_pages returns non zero, trace error
TRACFCOMP(g_trac_errl, ERR_MRK "Fail to flush the page %p size %d",
l_pnorAddr, l_errSize);
}
#endif
}
else
{
// flatten didn't work, so still return true - we don't want
// to try to save this errlog.
TRACFCOMP( g_trac_errl, ERR_MRK"saveErrLogToPnor: could not flatten data");
// restore slot so that our next save will find this slot
iv_pnorOpenSlot = l_previousSlot;
}
rc = true;
}
// else no open slot - return false
} while (0);
TRACFCOMP( g_trac_errl, EXIT_MRK"saveErrLogToPnor returning %s",
rc ? "true" : "false");
return rc;
} // saveErrLogToPnor
///////////////////////////////////////////////////////////////////////////////
// ErrlManager::ackErrLogInPnor()
///////////////////////////////////////////////////////////////////////////////
bool ErrlManager::ackErrLogInPnor( uint32_t i_errEid )
{
TRACFCOMP( g_trac_errl, ENTER_MRK"ackErrLogInPnor(%.8x)", i_errEid);
bool rc = true;
// look for an un-ACKed log that matches this eid
uint32_t i;
for (i = 0; i < iv_maxErrlInPnor; i++)
{
if (!isSlotEmpty(i) && !isSlotACKed(i))
{
uint32_t l_eid = readEidFromFlattened(i);
if (l_eid == i_errEid)
{
TRACDCOMP( g_trac_errl, INFO_MRK"ackErrLogInPnor: match in slot %d", i);
setACKInFlattened(i);
break;
}
}
} // for
// if we made it through the loop w/out breaking early
if (i == iv_maxErrlInPnor)
{
//could not find the errorlog to mark for acknowledgment
TRACDCOMP( g_trac_errl, ERR_MRK"ackErrLogInPnor failed to find the error log" );
rc = false;
}
TRACFCOMP( g_trac_errl, EXIT_MRK"ackErrLogInPnor returning %s",
rc ? "true" : "false");
return rc;
} // ackErrLogInPnor
bool ErrlManager::isSlotEmpty(uint32_t i_position)
{
// checks the first word of the flattened errlog, which should be a
// pelsectionheader - which will NEVER be 0xFFFFFFFF if it's valid.
char * l_pnorAddr = iv_pnorAddr + (PNOR_ERROR_LENGTH * i_position);
bool rc = (memcmp(l_pnorAddr, &EMPTY_ERRLOG_IN_PNOR, sizeof(uint32_t))
== 0);
TRACDCOMP( g_trac_errl, "isSlotEmpty: slot %d @ %p is %s",
i_position, l_pnorAddr, rc ? "empty" : "not empty");
return rc;
}
// readEidFromFlattened()
// i_position MUST be valid errlog (not EMPTY_ERRLOG_IN_PNOR)
uint32_t ErrlManager::readEidFromFlattened(uint32_t i_position)
{
const char * l_pnorAddr = iv_pnorAddr + (PNOR_ERROR_LENGTH * i_position);
const pelPrivateHeaderSection_t *pPH =
reinterpret_cast<const pelPrivateHeaderSection_t *>(l_pnorAddr);
TRACDCOMP(g_trac_errl, "readEid(%d): eid %.8x", i_position, pPH->eid);
return pPH->eid;
}
// readPlidFromFlattened()
// i_position MUST be valid errlog (not EMPTY_ERRLOG_IN_PNOR)
uint32_t ErrlManager::readPlidFromFlattened(uint32_t i_position)
{
const char * l_pnorAddr = iv_pnorAddr + (PNOR_ERROR_LENGTH * i_position);
const pelPrivateHeaderSection_t *pPH =
reinterpret_cast<const pelPrivateHeaderSection_t *>(l_pnorAddr);
TRACDCOMP(g_trac_errl, "readEid(%d): plid %.8x", i_position, pPH->plid);
return pPH->plid;
}
// isSlotACKed()
// i_position MUST be valid errlog (not EMPTY_ERRLOG_IN_PNOR)
bool ErrlManager::isSlotACKed(uint32_t i_position)
{
const char * l_pnorAddr = iv_pnorAddr + (PNOR_ERROR_LENGTH * i_position);
l_pnorAddr += sizeof(pelPrivateHeaderSection_t);
l_pnorAddr += sizeof(pelUserHeaderSection_t);
const pelSRCSection_t *pSRC =
reinterpret_cast<const pelSRCSection_t *>(l_pnorAddr);
TRACDCOMP(g_trac_errl, "isSlotACKed(%d): word5 %08x - %s",
i_position, pSRC->word5,
(pSRC->word5 & ErrlSrc::ACK_BIT) ? "not ACKed" : "ACKed");
return (pSRC->word5 & ErrlSrc::ACK_BIT) ? false : true;
}
// setACKInFlattened()
void ErrlManager::setACKInFlattened(uint32_t i_position)
{
char * l_pnorErrlAddr = iv_pnorAddr + (PNOR_ERROR_LENGTH * i_position);
char * l_pnorAddr = l_pnorErrlAddr + sizeof(pelPrivateHeaderSection_t);
l_pnorAddr += sizeof(pelUserHeaderSection_t);
pelSRCSection_t *pSRC = reinterpret_cast<pelSRCSection_t *>(l_pnorAddr);
pSRC->word5 &= ~(ErrlSrc::ACK_BIT);
TRACDCOMP(g_trac_errl, "setACKInFlattened(%d): word5 %08x - %s",
i_position, pSRC->word5,
(pSRC->word5 & ErrlSrc::ACK_BIT) ? "not ACKed" : "ACKed");
return;
}
#ifdef CONFIG_BMC_IPMI
void getSensorOffsetBasedOnSeverity(errlHndl_t & io_err,
uint8_t &o_eventDirType,
uint8_t & o_offset );
// helper function to gather sensor information
uint8_t getSensorInfo(HWAS::callout_ud_t *i_ud,
uint8_t* o_sensorNumber,
uint8_t* o_eventOffset,
errlHndl_t& io_error );
// SensorModifier is a class that detects certain procedure callouts that
// can override the sensors generated by hardware callouts.
// For example, a memory plugging error can override a hardware callout
// of type memory in order to indicate a "configuration error" occured
// See errlmanager.H for more info
// The constructor initializes flags for procedure callouts.
inline SensorModifier::SensorModifier()
{
iv_flag = 0;
};
// Consider this callout as a potential sensor modifier
inline void SensorModifier::considerCallout(HWAS::callout_ud_t *i_ud)
{
if (i_ud->type == HWAS::PROCEDURE_CALLOUT &&
i_ud->procedure == HWAS::EPUB_PRC_MEMORY_PLUGGING_ERROR)
{
iv_flag |= memory_plugging_error_mask;
}
else if (i_ud->type == HWAS::PROCEDURE_CALLOUT &&
(i_ud->procedure == HWAS::EPUB_PRC_PROC_AB_BUS ||
i_ud->procedure == HWAS::EPUB_PRC_PROC_XYZ_BUS ||
i_ud->procedure == HWAS::EPUB_PRC_EIBUS_ERROR)
)
{
iv_flag |= bus_error_mask;
}
else if (i_ud->type == HWAS::PROCEDURE_CALLOUT &&
i_ud->procedure == HWAS::EPUB_PRC_MEMBUS_ERROR)
{
iv_flag |= membus_error_mask;
}
};
// Modify the sensor if flag was set for that sensor.
inline bool SensorModifier::modifySensor(uint8_t i_sensorType,
uint8_t& o_eventDirType, uint8_t& o_specificOffset)
{
bool l_retval = false;
if( (iv_flag & memory_plugging_error_mask) &&
// we had a memory configuration error
i_sensorType == TARGETING::SENSOR_TYPE_MEMORY)
{
o_eventDirType = IPMISEL::sensor_specific;
// 0x6f Sensor-specific Offset
o_specificOffset = IPMISEL::mem_event_configuration_error;
// 0x07 Configuration Error
// modified
l_retval = true;
}
else if ( (iv_flag & bus_error_mask || iv_flag & membus_error_mask) &&
i_sensorType == TARGETING::SENSOR_TYPE_PROCESSOR)
{
o_eventDirType = IPMISEL::sensor_specific;
o_specificOffset = IPMISEL::proc_event_correctable_mach_check_err;
// 0x0Ch Correctable Machine Check Error
// modified;
l_retval = true;
}
else if ( (iv_flag & membus_error_mask) &&
i_sensorType == TARGETING::SENSOR_TYPE_MEMORY)
{
o_eventDirType = IPMISEL::sensor_specific;
o_specificOffset = IPMISEL::mem_event_device_disabled;
// 0x04 Memory device disabled
// modified;
l_retval = true;
}
return l_retval;
}
// Retrieve if informational/call-home eSELs are allowed to the BMC
bool ErrlManager::allowCallHomeEselsToBmc(void)
{
bool l_allowed = false;
uint8_t flag = 0;
TARGETING::Target* sys = nullptr;
TARGETING::targetService().getTopLevelTarget(sys);
if (sys)
{
flag = sys->getAttr<TARGETING::ATTR_ALLOW_CALLHOME_ESELS_TO_BMC>();
}
if (flag)
{
l_allowed = true;
}
return l_allowed;
}
///////////////////////////////////////////////////////////////////////////////
// ErrlManager::sendErrLogToBmc()
///////////////////////////////////////////////////////////////////////////////
void ErrlManager::sendErrLogToBmc(errlHndl_t &io_err, bool i_sendSels)
{
TRACFCOMP(g_trac_errl,
ENTER_MRK
"sendErrLogToBmc errlogId 0x%.8x, i_sendSels %d",
io_err->eid(), i_sendSels);
bool l_send_eSel_only = !i_sendSels; // don't send callout sensor SEL
bool l_callhome_type = false; // Is this a callhome type eSEL?
if (io_err->getEselCallhomeInfoEvent() && allowCallHomeEselsToBmc())
{
TRACFCOMP( g_trac_errl, INFO_MRK
"sendErrLogToBmc: setting l_callhome_type" );
l_callhome_type = true;
l_send_eSel_only = true; // just send eSEL without any callout SELs
}
do {
// keep track of procedure callouts that modify hardware callouts
SensorModifier l_modifier;
// Decide whether we want to skip the error log
if( io_err->getSkipShowingLog() && !l_callhome_type )
{
TRACFCOMP( g_trac_errl, INFO_MRK
"sendErrLogToBmc: %.8X is INFORMATIONAL/RECOVERED; skipping",
io_err->eid());
break;
}
// two pass algorithm to find the highest priority callout
// then send SELs for only the highest priority callouts
std::vector< HWAS::callout_ud_t* > l_callouts;
HWAS::callout_ud_t l_calloutToAdd; // used for EIBUS error
HWAS::callOutPriority l_priority = HWAS::SRCI_PRIORITY_NONE;
if (!l_send_eSel_only)
{
bool l_busCalloutEncountered = false; // flag bus callout
// look thru the errlog for any Callout UserDetail sections
// to later determine the sensor information for each SEL
// create a vector of callouts during the first pass
for(std::vector<ErrlUD*>::const_iterator
it = io_err->iv_SectionVector.begin();
it != io_err->iv_SectionVector.end();
it++ )
{
// if this is a CALLOUT
if ((ERRL_COMP_ID == (*it)->iv_header.iv_compId) &&
(1 == (*it)->iv_header.iv_ver) &&
(ERRL_UDT_CALLOUT == (*it)->iv_header.iv_sst) )
{
HWAS::callout_ud_t *l_ud =
reinterpret_cast<HWAS::callout_ud_t*>((*it)->iv_pData);
// create a "fill in" procedure callout for all bus callouts
if (l_ud->type == HWAS::BUS_CALLOUT)
{
l_busCalloutEncountered = true;
l_calloutToAdd.type = HWAS::PROCEDURE_CALLOUT;
l_calloutToAdd.procedure = HWAS::EPUB_PRC_EIBUS_ERROR;
}
// if this callout is higher than any previous callout
if (l_ud->priority > l_priority)
{
TRACFCOMP(g_trac_errl,
"sendErrLogToBmc new priority picked 0x%x > 0x%x",
l_ud->priority, l_priority );
// and update the priority
l_priority = l_ud->priority;
}
// consider as a potential modifier of other callouts
l_modifier.considerCallout(l_ud);
// add to list to be traversed in second pass
l_callouts.push_back(l_ud);
} // if callout
} // for each SectionVector
if (l_busCalloutEncountered)
{
// add EIBUS error procedure callout
// doing push_back after the loop and not during ensures that:
// 1) the iterator is not invalidated by the push_back
// 2) the push_back is done only once, even when there are
// multiple bus callouts (which is often). This would not
// be a major concern though since duplicates are removed
// in the next loop below.
l_callouts.push_back(&l_calloutToAdd);
// need to also consider this callout as a modifier of others
l_modifier.considerCallout(&l_calloutToAdd);
// our added callout always takes the highest priority seen
// so that it will not be dropped
l_calloutToAdd.priority = l_priority;
}
} // if i_sendSels
//Add additional user detail section to pel data after hw and procedure
//callouts to indicate esels from a previous boot.
if(!i_sendSels)
{
const char* l_prev_boot = "Error from a previous boot";
// Create a raw user-defined section. It does a copy of the
// string constant, then once added to io_err, io_err owns mem
ErrlUD* l_ffdcSection = new ErrlUD(l_prev_boot, strlen(l_prev_boot),
ERRL_COMP_ID, 1, ERRL_UDT_STRING );
io_err->iv_SectionVector.insert(io_err->iv_SectionVector.begin(),
l_ffdcSection);
}
// flatten into buffer, truncate to max eSEL size
TARGETING::Target * sys = NULL;
TARGETING::targetService().getTopLevelTarget( sys );
uint32_t l_maxBmcErrLogSize;
if ( sys &&
sys->tryGetAttr<TARGETING::ATTR_BMC_MAX_ERROR_LOG_SIZE>( l_maxBmcErrLogSize ) )
{
// (value was extracted from attributes)
}
else
{
// use default value for max log size
l_maxBmcErrLogSize = IPMISEL::ESEL_MAX_SIZE_DEFAULT;
TRACFCOMP( g_trac_errl, INFO_MRK
"sendErrLogToBmc: "
"Attribute ATTR_BMC_MAX_ERROR_LOG_SIZE not found, "
"ESEL_MAX_SIZE_DEFAULT used" );
}
uint32_t l_pelSize = io_err->flattenedSize();
if (l_pelSize > (l_maxBmcErrLogSize - sizeof(IPMISEL::selRecord)))
{
TRACFCOMP( g_trac_errl, INFO_MRK
"sendErrLogToBmc: msg size %d > %d, truncating.",
l_pelSize, l_maxBmcErrLogSize);
l_pelSize = l_maxBmcErrLogSize - sizeof(IPMISEL::selRecord);
}
uint8_t *l_pelData = new uint8_t[l_pelSize];
uint32_t l_errSize = io_err->flatten (l_pelData,
l_pelSize, true /* truncate */);
if (l_errSize == 0 )
{
// flatten didn't work
TRACFCOMP( g_trac_errl, ERR_MRK
"sendErrLogToBmc: could not flatten data - not sending");
delete [] l_pelData;
break;
}
// list of sels to be sent
std::vector<IPMISEL::sel_info_t*> l_selEventList;
// bool default constructor initializes to false as per C++ standard
std::map<uint8_t, bool> l_sensorNumberEncountered;
if (!l_send_eSel_only)
{
l_selEventList.clear();
std::vector<HWAS::callout_ud_t*>::const_iterator i;
for(i = l_callouts.begin(); i != l_callouts.end(); ++i)
{
uint8_t l_eventDirType[MAX_NUM_TARGETS] = {
IPMISEL::sensor_specific,
// this second element is only used for bus callouts
IPMISEL::sensor_specific};
uint8_t l_sensorNumber[MAX_NUM_TARGETS] = {
TARGETING::UTIL::INVALID_IPMI_SENSOR,
// this second element is only used for bus callouts
TARGETING::UTIL::INVALID_IPMI_SENSOR};
uint8_t l_eventOffset[MAX_NUM_TARGETS] = {
IPMISEL::event_data1_invalid_offset,
// this second element is only used for bus callouts
IPMISEL::event_data1_invalid_offset};
uint8_t l_sensorType[MAX_NUM_TARGETS] = { 0,
// this second element is only used for bus callouts
0};
// simplify callout notation
HWAS::callout_ud_t* l_ud = *i;
// populate l_sensorNumber and l_eventOffset with values
uint8_t l_num_targets = getSensorInfo(l_ud, l_sensorNumber,
l_eventOffset, io_err);
// if the offset is unknown at this point then it will
// be updated below by getSensorOffsetBasedOnSeverity
// l_num_targets is 2 for bus callouts, 1 otherwise
for (size_t j=0; j < l_num_targets; ++j)
{
// last ditch effort, if no sensor number is present at
// this point, just use the system event sensor
if( l_sensorNumber[j] ==
TARGETING::UTIL::INVALID_IPMI_SENSOR )
{
l_sensorNumber[j] =
TARGETING::UTIL::getSensorNumber(NULL,
TARGETING::SENSOR_NAME_SYSTEM_EVENT);
l_eventOffset[j] =
SENSOR::UNDETERMINED_SYSTEM_HW_FAILURE;
}
// grab the sensor type so the bmc knows how to use the
// offset
errlHndl_t l_errl =
IPMI::IpmiConfigLookup::getSensorType(l_sensorNumber[j],
l_sensorType[j]
);
if(l_errl)
{
TRACFCOMP(g_trac_errl,
ERR_MRK"Failed to get sensor type for sensor %d",
l_sensorNumber[j]);
l_sensorType[j] = 0;
delete l_errl;
l_errl = nullptr;
}
// this call will modify the sensor if any procedure
// callout is known to change its effect
bool l_wasModified = l_modifier.modifySensor(
l_sensorType[j], l_eventDirType[j], l_eventOffset[j]);
// if no offset has been configured set it based on the
// severity
if(l_eventOffset[j] == IPMISEL::event_data1_invalid_offset)
{
getSensorOffsetBasedOnSeverity(io_err,
l_eventDirType[j], l_eventOffset[j]);
}
// only send highest priority SELs or
// SELs of lesser priority that were modified
if (l_ud->priority == l_priority || l_wasModified)
{
// skip this iteration if we've seen this sensor
// number before
if (l_sensorNumberEncountered[l_sensorNumber[j]])
continue;
TRACFCOMP(g_trac_errl, INFO_MRK "sendErrLogToBmc:"
" sensor %.2x/%.2x event %x/%x, size %d",
l_sensorType[j], l_sensorNumber[j],
l_eventDirType[j], l_eventOffset[j], l_pelSize);
IPMISEL::sel_info_t *l_selEvent =
new(IPMISEL::sel_info_t);
l_selEvent->eventDirType = l_eventDirType[j];
l_selEvent->sensorNumber = l_sensorNumber[j];
l_selEvent->eventOffset = l_eventOffset[j];
l_selEvent->sensorType = l_sensorType[j];
// add to the list that goes out on the wire
l_selEventList.push_back(l_selEvent);
// make a note we've seen this sensor number before
l_sensorNumberEncountered[l_sensorNumber[j]] = true;
}
} // for l_num_targets
} // for l_callouts
if (l_selEventList.size())
{
IPMISEL::sendESEL(l_pelData, l_pelSize,
io_err->eid(),
l_selEventList,
l_callhome_type);
TRACFCOMP(g_trac_errl, INFO_MRK
"sendErrLogToBmc callout size %d",
l_selEventList.size());
}
}
else
{
// don't send sensor SELs
TRACFCOMP(g_trac_errl, INFO_MRK
"sendErrLogToBmc: no sensor SELs, size %d", l_pelSize );
l_selEventList.clear();
IPMISEL::sel_info_t *l_selEvent = new (IPMISEL::sel_info_t);
uint8_t l_eventDirType = IPMISEL::sensor_specific;
uint8_t l_eventOffset = IPMISEL::event_data1_invalid_offset;
l_selEvent->eventDirType = l_eventDirType;
l_selEvent->sensorNumber = TARGETING::UTIL::INVALID_IPMI_SENSOR;
l_selEvent->eventOffset = l_eventOffset;
l_selEvent->sensorType = SENSOR::INVALID_TYPE;
l_selEventList.push_back(l_selEvent);
IPMISEL::sendESEL(l_pelData, l_pelSize, io_err->eid(),
l_selEventList, l_callhome_type);
}
// free the buffer
delete [] l_pelData;
} while(0);
TRACFCOMP(g_trac_errl, EXIT_MRK "sendErrLogToBmc");
} // sendErrLogToBmc
uint8_t getSensorInfo(HWAS::callout_ud_t *i_ud,
uint8_t* o_sensorNumber, uint8_t* o_eventOffset,
errlHndl_t &io_err )
{
uint8_t l_num_sensors = 1;
// reset the offset, we will test and configure it later
*o_eventOffset = IPMISEL::event_data1_invalid_offset;
if( i_ud->type == HWAS::PROCEDURE_CALLOUT )
{
// for procedure callouts
*o_sensorNumber = TARGETING::UTIL::getSensorNumber(NULL,
TARGETING::SENSOR_NAME_SYSTEM_EVENT);
// For procedure callout, will have EPUB ID's.This data will be part of
// OEM SEL.
*o_eventOffset = i_ud->procedure;
TRACFCOMP(g_trac_errl,
"getSensorInfo o_eventOffset %d o_sensorNumber %d",
o_eventOffset,*o_sensorNumber);
}
// if its a clock callout or a its a part callout and its not
// the VPD part or the SBE EEPROM, then use the backplane fault
// sensor as these parts reside there.
else if((i_ud->type == HWAS::CLOCK_CALLOUT ) ||
((i_ud->type == HWAS::PART_CALLOUT ) &&
!((i_ud->partType == HWAS::VPD_PART_TYPE ) ||
(i_ud->partType == HWAS::SBE_SEEPROM_PART_TYPE))
))
{
*o_sensorNumber = SENSOR::getBackPlaneFaultSensor();
}
else if (i_ud->type == HWAS::SENSOR_CALLOUT )
{
*o_sensorNumber = static_cast<uint8_t>(i_ud->sensorId);
}
else
{
// for all other types there will be at least
// one target in the next user data section, we will use
// that target to find the fault sensor.
//
// NOTE: if the provided target does not have a fault sensor, the
// physical path will be used to determine the parent FRU which has
// a fault sensor associated with it.
uint8_t * l_uData = (uint8_t *)(i_ud + 1);
TARGETING::Target *l_target = NULL;
bool l_err = HWAS::retrieveTarget(l_uData, l_target, io_err);
if (!l_err)
{
// got a target, now get the sensor number
*o_sensorNumber = SENSOR::getFaultSensorNumber(l_target);
}
else
{
// couldnt expand the target so we are unable to get
// a sensor number - use the event sensor for this one
*o_sensorNumber = TARGETING::UTIL::getSensorNumber(NULL,
TARGETING::SENSOR_NAME_SYSTEM_EVENT);
*o_eventOffset = SENSOR::UNDETERMINED_SYSTEM_HW_FAILURE;
}
if (i_ud->type == HWAS::BUS_CALLOUT)
{
l_err = HWAS::retrieveTarget(l_uData, l_target, io_err);
if (!l_err)
{
o_sensorNumber[l_num_sensors] =
SENSOR::getFaultSensorNumber(l_target);
l_num_sensors++;
}
}
}
return l_num_sensors;
}
void getSensorOffsetBasedOnSeverity(errlHndl_t & io_err,
uint8_t &o_eventDirType,
uint8_t & o_eventOffset )
{
switch (io_err->sev())
{
case ERRORLOG::ERRL_SEV_INFORMATIONAL:
o_eventDirType = IPMISEL::event_transition;
o_eventOffset = IPMISEL::event_data1_trans_informational;
break;
case ERRL_SEV_RECOVERED:
o_eventDirType = IPMISEL::event_transition;
o_eventOffset = IPMISEL::event_data1_trans_to_ok;
break;
case ERRL_SEV_PREDICTIVE:
o_eventDirType = IPMISEL::event_predictive;
o_eventOffset = IPMISEL::event_data1_trans_to_noncrit_from_ok;
break;
case ERRL_SEV_UNRECOVERABLE:
o_eventDirType = IPMISEL::event_transition;
o_eventOffset = IPMISEL::event_data1_trans_to_non_recoverable;
break;
case ERRL_SEV_CRITICAL_SYS_TERM:
o_eventDirType = IPMISEL::event_transition;
o_eventOffset = IPMISEL::event_data1_trans_to_crit_from_non_r;
break;
case ERRL_SEV_UNKNOWN:
o_eventDirType = IPMISEL::event_state;
o_eventOffset = IPMISEL::event_data1_asserted;
break;
default:
o_eventDirType = IPMISEL::sensor_specific;
o_eventOffset = IPMISEL::event_data1_trans_to_non_recoverable;
break;
}
}
#endif // CONFIG_BMC_IPMI
void ErrlManager::setErrlSkipFlag(errlHndl_t io_err)
{
// Note: iv_skipShowingLog is set to True by default
//0 = Prevent INFORMATIONAL/RECOVERED error logs from being processed.
//1 = Send only INFORMATIONAL error logs.
//2 = Send only RECOVERED error logs.
//3 = Allow all hidden error logs to be processed.
//Check severity
switch (io_err->sev())
{
case ERRORLOG::ERRL_SEV_INFORMATIONAL:
// check if we are allowing info logs through.
if((iv_hiddenErrLogsEnable ==
TARGETING::
HIDDEN_ERRLOGS_ENABLE_ALLOW_INFORMATIONAL)||
(iv_hiddenErrLogsEnable ==
TARGETING::
HIDDEN_ERRLOGS_ENABLE_ALLOW_ALL_LOGS))
{
io_err->setSkipShowingLog(false);
}
break;
case ERRORLOG::ERRL_SEV_RECOVERED:
// check if we are allowing recovered logs through.
if(((iv_hiddenErrLogsEnable ==
TARGETING::
HIDDEN_ERRLOGS_ENABLE_ALLOW_RECOVERED) ||
(iv_hiddenErrLogsEnable ==
TARGETING::
HIDDEN_ERRLOGS_ENABLE_ALLOW_ALL_LOGS)) &&
!iv_isSpBaseServices)
{
//Recovered error logs that are encountered
//before targeting and initservice are loaded,
//will still be queued for sending to PNOR/IPMI
io_err->setSkipShowingLog(false);
}
break;
default:
// For any error log that is not INFORMATIONAL
// or RECOVERED, we want to show the log
io_err->setSkipShowingLog(false);
}
} // setErrlSkipFlag
} // end namespace
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