/**
* @brief Handles MCS Channel fail bits, if they exist.
*
* @param i_membChip The Centaur chip.
* @param i_sc ServiceDataColector.
*
* @return SUCCESS if MCS channel fail is present and properly
* handled, FAIL otherwise.
*/
int32_t handleMcsChnlCs( ExtensibleChip * i_membChip,
STEP_CODE_DATA_STRUCT & i_sc )
{
#define PRDF_FUNC "[handleMcsChnlCs] "
// We will return FAIL from this function if MCS channel fail bits
// are not set. If MCS channel fail bits are set, we will try to analyze
// Mcs. If MCS is not analyzed properly, we will return FAIL.
// This will trigger rule code to execute alternate resolution.
int32_t l_rc = SUCCESS;
do
{
CenMembufDataBundle * mbdb = getMembufDataBundle( i_membChip );
ExtensibleChip * mcsChip = mbdb->getMcsChip();
if( NULL == mcsChip )
{
l_rc = FAIL;
break;
}
SCAN_COMM_REGISTER_CLASS * mciFir = mcsChip->getRegister("MCIFIR");
SCAN_COMM_REGISTER_CLASS * mciFirMask =
mcsChip->getRegister("MCIFIR_MASK");
l_rc = mciFir->Read();
l_rc |= mciFirMask->Read();
if ( SUCCESS != l_rc )
{
PRDF_ERR( PRDF_FUNC"MCIFIR/MCIFIR_MASK read failed for 0x%08x",
mcsChip->GetId());
break;
}
// If any of MCS channel fail bit is set, we will analyze
// MCS. It is safe to do hard coded check as channel fail
// bits are hard wired and and they can not change without HW
// change.
// bits 0,1, 6, 8, 9, 22, 23, 40 are channel fail bits.
uint64_t chnlCsBitsMask = 0xC2C0030000800000ull;
uint64_t mciFirBits = mciFir->GetBitFieldJustified(0, 64);
uint64_t mciFirMaskBits = mciFirMask->GetBitFieldJustified(0, 64);
if ( mciFirBits & ~mciFirMaskBits & chnlCsBitsMask )
{
l_rc = mcsChip->Analyze( i_sc,
i_sc.service_data->GetCauseAttentionType() );
if( SUCCESS == l_rc ) break;
}
l_rc = FAIL;
}while( 0 );
return l_rc;
#undef PRDF_FUNC
} PRDF_PLUGIN_DEFINE( Membuf, handleMcsChnlCs );
/**
* @fn MaskMbaCalSecondaryBits
* @brief Mask MBACAL secondary Fir bits which may come up because of L4 UE.
* @param i_chip The Centaur chip.
* @param i_sc ServiceDataColector.
* @return SUCCESS.
*/
int32_t MaskMbaCalSecondaryBits( ExtensibleChip * i_chip,
STEP_CODE_DATA_STRUCT & i_sc )
{
#define PRDF_FUNC "[MaskMbaCalSecondaryBits ] "
int32_t l_rc = SUCCESS;
do
{
CenMembufDataBundle * membdb = getMembufDataBundle( i_chip );
for( uint32_t i = 0; i < MAX_MBA_PER_MEMBUF; i++ )
{
ExtensibleChip * mbaChip = membdb->getMbaChip(i);
if ( NULL == mbaChip ) continue;
SCAN_COMM_REGISTER_CLASS * mbaCalFirMaskOr =
mbaChip->getRegister("MBACALFIR_MASK_OR");
mbaCalFirMaskOr->SetBit(9);
mbaCalFirMaskOr->SetBit(15);
l_rc = mbaCalFirMaskOr->Write();
if ( SUCCESS != l_rc )
{
// Do not break. Just print error trace and look for
// other MBA.
PRDF_ERR( PRDF_FUNC"MBACALFIR_MASK_OR write failed"
"for 0x%08x", mbaChip->GetId());
}
}
}while( 0 );
return SUCCESS;
#undef PRDF_FUNC
} PRDF_PLUGIN_DEFINE( Membuf, MaskMbaCalSecondaryBits );
bool isSpareBitOnDMIBus( ExtensibleChip * i_mcsChip, ExtensibleChip * i_mbChip )
{
bool bitOn = false;
do
{
// If any of these object is NULL, spare bit should not be on.
if ( ( NULL == i_mcsChip ) || ( NULL == i_mbChip ))
break;
// check spare deployed bit on Centaur side
SCAN_COMM_REGISTER_CLASS * dmiFir = i_mbChip->getRegister( "DMIFIR" );
int32_t rc = dmiFir->Read();
if ( SUCCESS != rc )
{
PRDF_ERR("isSpareBitOnDMIBus() : Failed to read DMIFIR."
"MEMBUF: 0x%08X", getHuid( i_mbChip->GetChipHandle()) );
break;
}
if ( dmiFir->IsBitSet( 9 ))
{
bitOn = true;
break;
}
// check spare deployed bit on Proc side
TargetHandle_t mcsTgt = i_mcsChip->GetChipHandle();
TargetHandle_t procTgt = getConnectedParent( mcsTgt, TYPE_PROC );
ExtensibleChip * procChip =
( ExtensibleChip * )systemPtr->GetChip( procTgt );
uint32_t mcsPos = getTargetPosition( mcsTgt );
const char * regStr = ( 4 > mcsPos) ? "IOMCFIR_0" : "IOMCFIR_1";
SCAN_COMM_REGISTER_CLASS * iomcFir = procChip->getRegister( regStr );
rc = iomcFir->Read();
if ( SUCCESS != rc )
{
PRDF_ERR("isSpareBitOnDMIBus() : Failed to read %s."
"MCS: 0x%08X", regStr, getHuid(mcsTgt) );
break;
}
// Bit 9, 17, 25 and 33 are for spare deployed.
// Check bit corrosponding to MCS position
uint8_t bitPos = 9 + ( mcsPos % 4 ) *8;
if ( iomcFir->IsBitSet(bitPos))
{
bitOn = true;
}
}while(0);
return bitOn;
}
/**
* @brief Plugin to mask the side effects of an RCD parity error
* @param i_mbaChip A Centaur MBA chip.
* @param i_sc The step code data struct.
* @return SUCCESS
*/
int32_t maskRcdParitySideEffects( ExtensibleChip * i_mbaChip,
STEP_CODE_DATA_STRUCT & i_sc )
{
#define PRDF_FUNC "[maskRcdParitySideEffects] "
int32_t l_rc = SUCCESS;
do
{
//use a data bundle to get the membuf chip
CenMbaDataBundle * mbadb = getMbaDataBundle( i_mbaChip );
ExtensibleChip * membChip = mbadb->getMembChip();
if (NULL == membChip)
{
PRDF_ERR(PRDF_FUNC "getMembChip() failed");
break;
}
//get the masks for each FIR
SCAN_COMM_REGISTER_CLASS * mbsFirMaskOr =
membChip->getRegister("MBSFIR_MASK_OR");
SCAN_COMM_REGISTER_CLASS * mbaCalMaskOr =
i_mbaChip->getRegister("MBACALFIR_MASK_OR");
SCAN_COMM_REGISTER_CLASS * mbaFirMaskOr =
i_mbaChip->getRegister("MBAFIR_MASK_OR");
mbaFirMaskOr->SetBit(2);
mbaCalMaskOr->SetBit(2);
mbaCalMaskOr->SetBit(17);
mbsFirMaskOr->SetBit(4);
l_rc = mbaFirMaskOr->Write();
l_rc |= mbaCalMaskOr->Write();
l_rc |= mbsFirMaskOr->Write();
if (SUCCESS != l_rc)
{
PRDF_ERR(PRDF_FUNC "MBAFIR_MASK_OR/MBACALFIR_MASK_OR/MBSFIR_MASK_OR"
" write failed for 0x%08x", i_mbaChip->GetId());
break;
}
}while(0);
return SUCCESS;
#undef PRDF_FUNC
}
int32_t getDramSize( ExtensibleChip *i_mbaChip, uint8_t & o_size )
{
#define PRDF_FUNC "[MemUtils::getDramSize] "
int32_t o_rc = SUCCESS;
o_size = SIZE_2GB;
do
{
TargetHandle_t mbaTrgt = i_mbaChip->GetChipHandle();
CenMbaDataBundle * mbadb = getMbaDataBundle( i_mbaChip );
ExtensibleChip * membufChip = mbadb->getMembChip();
if ( NULL == membufChip )
{
PRDF_ERR( PRDF_FUNC "getMembChip() failed: MBA=0x%08x",
getHuid(mbaTrgt) );
o_rc = FAIL; break;
}
uint32_t pos = getTargetPosition(mbaTrgt);
const char * reg_str = (0 == pos) ? "MBA0_MBAXCR" : "MBA1_MBAXCR";
SCAN_COMM_REGISTER_CLASS * reg = membufChip->getRegister( reg_str );
o_rc = reg->Read();
if ( SUCCESS != o_rc )
{
PRDF_ERR( PRDF_FUNC "Read() failed on %s. Target=0x%08x",
reg_str, getHuid(mbaTrgt) );
break;
}
o_size = reg->GetBitFieldJustified( 6, 2 );
} while(0);
return o_rc;
#undef PRDF_FUNC
}
int32_t collectCeStats( ExtensibleChip * i_mbaChip, const CenRank & i_rank,
MaintSymbols & o_maintStats, CenSymbol & o_chipMark,
uint8_t i_thr )
{
#define PRDF_FUNC "[MemUtils::collectCeStats] "
int32_t o_rc = SUCCESS;
o_chipMark = CenSymbol(); // Initially invalid.
do
{
if ( 0 == i_thr ) // Must be non-zero
{
PRDF_ERR( PRDF_FUNC "i_thr %d is invalid", i_thr );
o_rc = FAIL; break;
}
TargetHandle_t mbaTrgt = i_mbaChip->GetChipHandle();
CenMbaDataBundle * mbadb = getMbaDataBundle( i_mbaChip );
ExtensibleChip * membufChip = mbadb->getMembChip();
if ( NULL == membufChip )
{
PRDF_ERR( PRDF_FUNC "getMembChip() failed" );
o_rc = FAIL; break;
}
uint8_t mbaPos = getTargetPosition( mbaTrgt );
if ( MAX_MBA_PER_MEMBUF <= mbaPos )
{
PRDF_ERR( PRDF_FUNC "mbaPos %d is invalid", mbaPos );
o_rc = FAIL; break;
}
const bool isX4 = isDramWidthX4(mbaTrgt);
// Get the current spares on this rank.
CenSymbol sp0, sp1, ecc;
o_rc = mssGetSteerMux( mbaTrgt, i_rank, sp0, sp1, ecc );
if ( SUCCESS != o_rc )
{
PRDF_ERR( PRDF_FUNC "mssGetSteerMux() failed." );
break;
}
// Use this map to keep track of the total counts per DRAM.
DramCountMap dramCounts;
const char * reg_str = NULL;
SCAN_COMM_REGISTER_CLASS * reg = NULL;
for ( uint8_t regIdx = 0; regIdx < CE_REGS_PER_MBA; regIdx++ )
{
reg_str = mbsCeStatReg[mbaPos][regIdx];
reg = membufChip->getRegister( reg_str );
o_rc = reg->Read();
if ( SUCCESS != o_rc )
{
PRDF_ERR( PRDF_FUNC "Read() failed on %s", reg_str );
break;
}
uint8_t baseSymbol = SYMBOLS_PER_CE_REG * regIdx;
for ( uint8_t i = 0; i < SYMBOLS_PER_CE_REG; i++ )
{
uint8_t count = reg->GetBitFieldJustified( (i*8), 8 );
if ( 0 == count ) continue; // nothing to do
uint8_t sym = baseSymbol + i;
uint8_t dram = symbol2Dram( sym, isX4 );
// Keep track of the total DRAM counts.
dramCounts[dram].totalCount += count;
// Add any symbols that have exceeded threshold to the list.
if ( i_thr <= count )
{
// Keep track of the total number of symbols per DRAM that
// have exceeded threshold.
dramCounts[dram].symbolCount++;
SymbolData symData;
symData.symbol = CenSymbol::fromSymbol( mbaTrgt, i_rank,
sym, CEN_SYMBOL::BOTH_SYMBOL_DQS );
if ( !symData.symbol.isValid() )
{
PRDF_ERR( PRDF_FUNC "CenSymbol() failed: symbol=%d",
sym );
o_rc = FAIL;
break;
}
else
{
// Check if this symbol is on any of the spares.
if ( ( sp0.isValid() &&
(sp0.getDram() == symData.symbol.getDram()) ) ||
( sp1.isValid() &&
(sp1.getDram() == symData.symbol.getDram()) ) )
{
symData.symbol.setDramSpared();
}
if ( ecc.isValid() &&
(ecc.getDram() == symData.symbol.getDram()) )
{
symData.symbol.setEccSpared();
}
// Add the symbol to the list.
symData.count = count;
o_maintStats.push_back( symData );
}
}
}
if ( SUCCESS != o_rc ) break;
}
if ( SUCCESS != o_rc ) break;
if ( o_maintStats.empty() ) break; // no need to continue
// Sort the list of symbols.
std::sort( o_maintStats.begin(), o_maintStats.end(), sortSymDataCount );
// Get the DRAM with the highest count.
uint32_t highestDram = 0;
uint32_t highestCount = 0;
const uint32_t symbolTH = isX4 ? 1 : 2;
for ( DramCountMap::iterator it = dramCounts.begin();
it != dramCounts.end(); ++it )
{
if ( (symbolTH <= it->second.symbolCount) &&
(highestCount < it->second.totalCount ) )
{
highestDram = it->first;
highestCount = it->second.totalCount;
}
}
if ( 0 != highestCount )
{
uint8_t sym = dram2Symbol( highestDram, isX4 );
o_chipMark = CenSymbol::fromSymbol( mbaTrgt, i_rank, sym );
// Check if this symbol is on any of the spares.
if ( ( sp0.isValid() && (sp0.getDram() == o_chipMark.getDram()) ) ||
( sp1.isValid() && (sp1.getDram() == o_chipMark.getDram()) ) )
{
o_chipMark.setDramSpared();
}
if ( ecc.isValid() && (ecc.getDram() == o_chipMark.getDram()) )
{
o_chipMark.setEccSpared();
}
}
} while(0);
if ( SUCCESS != o_rc )
{
PRDF_ERR( PRDF_FUNC "Failed: i_mbaChip=0x%08x i_rank=m%ds%d i_thr=%d",
i_mbaChip->GetId(), i_rank.getMaster(), i_rank.getSlave(),
i_thr );
}
return o_rc;
#undef PRDF_FUNC
}
int32_t chnlCsCleanup( ExtensibleChip *i_mbChip,
STEP_CODE_DATA_STRUCT & i_sc )
{
#define PRDF_FUNC "[MemUtils::chnlCsCleanup] "
int32_t o_rc = SUCCESS;
do
{
if( ( NULL == i_mbChip ) ||
( TYPE_MEMBUF != getTargetType( i_mbChip->GetChipHandle() )))
{
PRDF_ERR( PRDF_FUNC "Invalid parameters" );
o_rc = FAIL; break;
}
if (( ! i_sc.service_data->IsUnitCS() ) ||
(CHECK_STOP == i_sc.service_data->getPrimaryAttnType()) )
break;
CenMembufDataBundle * mbdb = getMembufDataBundle( i_mbChip );
if ( !mbdb->iv_doChnlFailCleanup )
break; // Cleanup has already been done.
// Set it as SUE generation point.
i_sc.service_data->SetFlag( ServiceDataCollector::UERE );
ExtensibleChip * mcsChip = mbdb->getMcsChip();
if ( NULL == mcsChip )
{
PRDF_ERR( PRDF_FUNC "MCS chip is NULL for Membuf:0x%08X",
i_mbChip->GetId() );
o_rc = FAIL; break;
}
TargetHandle_t mcs = mcsChip->GetChipHandle();
ExtensibleChip * procChip = NULL;
uint8_t pos = getTargetPosition( mcs );
TargetHandle_t proc = getParentChip ( mcs );
if ( NULL == proc )
{
PRDF_ERR( PRDF_FUNC "Proc is NULL for Mcs:0x%08X", getHuid( mcs ) );
o_rc = FAIL; break;
}
procChip = (ExtensibleChip *)systemPtr->GetChip( proc );
if( NULL == procChip )
{
PRDF_ERR( PRDF_FUNC "Can not find Proc chip for HUID:0x%08X",
getHuid( proc) );
o_rc = FAIL; break;
}
// This is a cleanup function. If we get any error from scom
// operations, we will still continue with cleanup.
SCAN_COMM_REGISTER_CLASS * l_tpMask =
procChip->getRegister("TP_CHIPLET_FIR_MASK");
o_rc |= l_tpMask->Read();
if ( SUCCESS == o_rc )
{
// Bits 5-12 maps to attentions from MCS0-MCS7.
l_tpMask->SetBit( 5 + pos );
o_rc |= l_tpMask->Write();
}
// Mask attentions from the Centaur
const char *iomcFirMask = ( pos < 4 )?
"IOMCFIR_0_MASK_OR":"IOMCFIR_1_MASK_OR";
SCAN_COMM_REGISTER_CLASS * iomcMask =
procChip->getRegister( iomcFirMask);
if ( pos >= 4 ) pos -= 4;
// 8 bits are reserved for each Centaur in IOMCFIR.
// There are total 4 ( for P system ) centaur supported
// in MCS. Bits for first centaur starts from bit 8.
iomcMask->SetBitFieldJustified( 8+ ( pos*8 ), 8, 0xff);
o_rc |= iomcMask->Write();
SCAN_COMM_REGISTER_CLASS * l_tpfirmask = NULL;
SCAN_COMM_REGISTER_CLASS * l_nestfirmask = NULL;
SCAN_COMM_REGISTER_CLASS * l_memfirmask = NULL;
SCAN_COMM_REGISTER_CLASS * l_memspamask = NULL;
l_tpfirmask = i_mbChip->getRegister("TP_CHIPLET_FIR_MASK");
l_nestfirmask = i_mbChip->getRegister("NEST_CHIPLET_FIR_MASK");
l_memfirmask = i_mbChip->getRegister("MEM_CHIPLET_FIR_MASK");
l_memspamask = i_mbChip->getRegister("MEM_CHIPLET_SPA_MASK");
l_tpfirmask->setAllBits(); o_rc |= l_tpfirmask->Write();
l_nestfirmask->setAllBits(); o_rc |= l_nestfirmask->Write();
l_memfirmask->setAllBits(); o_rc |= l_memfirmask->Write();
l_memspamask->setAllBits(); o_rc |= l_memspamask->Write();
for ( uint32_t i = 0; i < MAX_MBA_PER_MEMBUF; i++ )
{
ExtensibleChip * mbaChip = mbdb->getMbaChip( i );
if( NULL != mbaChip )
{
TargetHandle_t mba = mbaChip->GetChipHandle();
if ( NULL != mba )
{
#if defined(__HOSTBOOT_MODULE) && \
!defined(__HOSTBOOT_RUNTIME)
// This is very small platform specific code. So not
// creating a separate file for this.
int32_t l_rc = mdiaSendEventMsg( mba, MDIA::SKIP_MBA );
if ( SUCCESS != l_rc )
{
PRDF_ERR( PRDF_FUNC "mdiaSendEventMsg(0x%08x, SKIP_MBA) "
"failed", getHuid( mba ) );
o_rc |= l_rc;
}
#else
int32_t l_rc = DEALLOC::mbaGard( mbaChip );
if ( SUCCESS != l_rc )
{
PRDF_ERR( PRDF_FUNC "mbaGard failed. HUID: 0x%08x",
getHuid( mba ) );
o_rc |= l_rc;
}
#endif // __HOSTBOOT_MODULE
}
}
}
// Clean up complete an is no longer required.
mbdb->iv_doChnlFailCleanup = false;
} while(0);
return o_rc;
#undef PRDF_FUNC
}
void addMemChipletFirRegs( ExtensibleChip * i_membChip, CaptureData & io_cd )
{
#define PRDF_FUNC "[CenMbaCaptureData::addMemChipletFirRegs] "
int32_t l_rc = SUCCESS;
do
{
if ( NULL == i_membChip )
{
PRDF_ERR( PRDF_FUNC "Given target is NULL" );
break;
}
if ( TYPE_MEMBUF != getTargetType(i_membChip->GetChipHandle()) )
{
PRDF_ERR( PRDF_FUNC "Invalid target type: i_membChip=0x%08x",
i_membChip->GetId() );
break;
}
SCAN_COMM_REGISTER_CLASS * cs_global, * re_global, * spa_global;
cs_global = i_membChip->getRegister("GLOBAL_CS_FIR");
re_global = i_membChip->getRegister("GLOBAL_RE_FIR");
spa_global = i_membChip->getRegister("GLOBAL_SPA");
l_rc = cs_global->Read() | re_global->Read() | spa_global->Read();
if ( SUCCESS != l_rc )
{
PRDF_ERR( PRDF_FUNC "Failed to read a GLOBAL register on "
"0x%08x", i_membChip->GetId() );
break;
}
// If global bit 3 is not on, can't scom mem chiplets or mba's
if( ! (cs_global->IsBitSet(3) ||
re_global->IsBitSet(3) ||
spa_global->IsBitSet(3)) )
{
break;
}
i_membChip->CaptureErrorData(io_cd,
Util::hashString("MemChipletRegs"));
CenMembufDataBundle * membdb = getMembufDataBundle( i_membChip );
for ( uint32_t i = 0; i < MAX_MBA_PER_MEMBUF; i++ )
{
ExtensibleChip * mbaChip = membdb->getMbaChip(i);
if ( NULL == mbaChip )
{
PRDF_ERR( PRDF_FUNC "MEM_CHIPLET registers indicated an "
"attention but no chip found: i_membChip=0x%08x "
"i=%d", i_membChip->GetId(), i );
continue;
}
mbaChip->CaptureErrorData(io_cd,
Util::hashString("MemChipletRegs") );
}
} while (0);
#undef PRDF_FUNC
}
/**
* @fn ClearMbaCalSecondaryBits
* @brief Clears MBACAL secondary Fir bits which may come up because of MBSFIR
* @param i_chip The Centaur chip.
* @param i_sc ServiceDataColector.
* @return SUCCESS.
*/
int32_t ClearMbaCalSecondaryBits( ExtensibleChip * i_chip,
STEP_CODE_DATA_STRUCT & i_sc )
{
#define PRDF_FUNC "[ClearMbaCalSecondaryBits ] "
int32_t l_rc = SUCCESS;
do
{
SCAN_COMM_REGISTER_CLASS * mbsFir = i_chip->getRegister("MBSFIR");
SCAN_COMM_REGISTER_CLASS * mbsFirMask =
i_chip->getRegister("MBSFIR_MASK");
l_rc = mbsFir->Read();
l_rc |= mbsFirMask->Read();
if ( SUCCESS != l_rc )
{
PRDF_ERR( PRDF_FUNC"MBSFIR/MBSFIR_MASK read failed"
"for 0x%08x", i_chip->GetId());
break;
}
CenMembufDataBundle * membdb = getMembufDataBundle( i_chip );
for( uint32_t i = 0; i < MAX_MBA_PER_MEMBUF; i++ )
{
ExtensibleChip * mbaChip = membdb->getMbaChip(i);
if ( NULL == mbaChip ) continue;
SCAN_COMM_REGISTER_CLASS * mbaCalFir =
mbaChip->getRegister("MBACALFIR");
if( SUCCESS != mbaCalFir->Read() )
{
// Do not break. Just print error trace and look for
// other MBA.
PRDF_ERR( PRDF_FUNC"MBACALFIR read failed"
"for 0x%08x", mbaChip->GetId());
continue;
}
if( !( mbaCalFir->IsBitSet( 10 ) || mbaCalFir->IsBitSet( 14 ) ))
continue;
SCAN_COMM_REGISTER_CLASS * mbaCalAndFir =
mbaChip->getRegister("MBACALFIR_AND");
mbaCalAndFir->setAllBits();
mbaCalAndFir->ClearBit(10);
mbaCalAndFir->ClearBit(14);
l_rc = mbaCalAndFir->Write();
if ( SUCCESS != l_rc )
{
// Do not break. Just print error trace and look for
// other MBA.
PRDF_ERR( PRDF_FUNC"MBACALFIR_AND write failed"
"for 0x%08x", mbaChip->GetId());
}
}
}while( 0 );
return SUCCESS;
#undef PRDF_FUNC
} PRDF_PLUGIN_DEFINE( Membuf, ClearMbaCalSecondaryBits );
/**
* @brief MBSECCFIR[19] - Fetch UE.
* @param i_membChip A Centaur chip.
* @param i_sc The step code data struct.
* @param i_mbaPos The MBA position.
* @return SUCCESS
*/
int32_t AnalyzeFetchUe( ExtensibleChip * i_membChip,
STEP_CODE_DATA_STRUCT & i_sc, uint32_t i_mbaPos )
{
#define PRDF_FUNC "[AnalyzeFetchUe] "
int32_t l_rc = SUCCESS;
ExtensibleChip * mbaChip = NULL;
do
{
// All memory UEs should be customer viewable. Normally, this would be
// done by setting the threshold to 1, but we do not want to mask UEs
// on the first occurrence.
i_sc.service_data->SetServiceCall();
CenMembufDataBundle * membdb = getMembufDataBundle( i_membChip );
mbaChip = membdb->getMbaChip( i_mbaPos );
if ( NULL == mbaChip )
{
PRDF_ERR( PRDF_FUNC"getMbaChip() returned NULL" );
l_rc = FAIL; break;
}
CenAddr addr;
l_rc = getCenReadAddr( i_membChip, i_mbaPos, READ_UE_ADDR, addr );
if ( SUCCESS != l_rc )
{
PRDF_ERR( PRDF_FUNC"getCenReadAddr() failed" );
break;
}
CenRank rank = addr.getRank();
// Add address to UE table.
CenMbaDataBundle * mbadb = getMbaDataBundle( mbaChip );
mbadb->iv_ueTable.addEntry( UE_TABLE::FETCH_UE, addr );
// Callout the rank.
MemoryMru memmru ( mbaChip->GetChipHandle(), rank,
MemoryMruData::CALLOUT_RANK );
i_sc.service_data->SetCallout( memmru );
// Add a TPS request to the TD queue and ban any further TPS requests
// for this rank.
l_rc = mbadb->iv_tdCtlr.handleTdEvent( i_sc, rank,
CenMbaTdCtlrCommon::TPS_EVENT,
true );
if ( SUCCESS != l_rc )
{
PRDF_ERR( PRDF_FUNC"handleTdEvent() failed: rank=m%ds%d",
rank.getMaster(), rank.getSlave() );
// We are not adding break here as we still want to do lmbGard
// If you want to add any code after this which depends on result
// of handleTdEvent result, add the code judicially.
}
#ifndef __HOSTBOOT_MODULE
// Send lmb gard message to PHYP.
int32_t lmbRc = DEALLOC::lmbGard( mbaChip, addr );
if ( SUCCESS != lmbRc )
{
PRDF_ERR( PRDF_FUNC"lmbGard() failed" );
l_rc = lmbRc; break;
}
#endif
} while (0);
// Add ECC capture data for FFDC.
if ( NULL != mbaChip )
CenMbaCaptureData::addMemEccData( mbaChip, i_sc );
if ( SUCCESS != l_rc )
{
PRDF_ERR( PRDF_FUNC"Failed: i_membChip=0x%08x i_mbaPos=%d",
i_membChip->GetId(), i_mbaPos );
CalloutUtil::defaultError( i_sc );
}
return SUCCESS; // Intentionally return SUCCESS for this plugin
#undef PRDF_FUNC
}
/**
* @brief Fetch Retry CE / Prefetch UE Errors.
* @param i_membChip A Centaur chip.
* @param i_sc The step code data struct.
* @param i_mbaPos The MBA position.
* @param i_isRceError True for RCE error false otherwise.
* @return SUCCESS
*/
int32_t AnalyzeFetchRcePue( ExtensibleChip * i_membChip,
STEP_CODE_DATA_STRUCT & i_sc, uint32_t i_mbaPos,
bool i_isRceError )
{
#define PRDF_FUNC "[AnalyzeFetchRcePue] "
int32_t l_rc = SUCCESS;
ExtensibleChip * mbaChip = NULL;
do
{
CenMembufDataBundle * membdb = getMembufDataBundle( i_membChip );
mbaChip = membdb->getMbaChip( i_mbaPos );
if ( NULL == mbaChip )
{
PRDF_ERR( PRDF_FUNC"getMbaChip() returned NULL" );
l_rc = FAIL; break;
}
CenMbaDataBundle * mbadb = getMbaDataBundle( mbaChip );
CenAddr addr;
if ( i_isRceError )
l_rc = getCenReadAddr( i_membChip, i_mbaPos, READ_RCE_ADDR, addr );
else
l_rc = getCenReadAddr( i_membChip, i_mbaPos, READ_UE_ADDR, addr );
if ( SUCCESS != l_rc )
{
PRDF_ERR( PRDF_FUNC"getCenReadAddr() failed" );
break;
}
CenRank rank = addr.getRank();
// Callout the rank.
MemoryMru memmru ( mbaChip->GetChipHandle(), rank,
MemoryMruData::CALLOUT_RANK );
i_sc.service_data->SetCallout( memmru );
// Add an entry to the RCE table.
if ( mbadb->iv_rceTable.addEntry(rank, i_sc) )
{
// Add a TPS request to the queue TD queue.
l_rc = mbadb->iv_tdCtlr.handleTdEvent( i_sc, rank,
CenMbaTdCtlrCommon::TPS_EVENT );
if ( SUCCESS != l_rc )
{
PRDF_ERR( PRDF_FUNC"handleTdEvent() failed." );
break;
}
}
} while (0);
// Add ECC capture data for FFDC.
if ( NULL != mbaChip )
CenMbaCaptureData::addMemEccData( mbaChip, i_sc );
if ( SUCCESS != l_rc )
{
PRDF_ERR( PRDF_FUNC"Failed: i_membChip=0x%08x i_mbaPos=%d "
"i_isRceError=%c", i_membChip->GetId(), i_mbaPos,
i_isRceError ? 'T' : 'F' );
CalloutUtil::defaultError( i_sc );
}
return SUCCESS; // Intentionally return SUCCESS for this plugin
#undef PRDF_FUNC
}
/**
* @brief MBSECCFIR[16] - Fetch New CE (NCE).
* @param i_membChip A Centaur chip.
* @param i_sc The step code data struct.
* @param i_mbaPos The MBA position.
* @return SUCCESS
*/
int32_t AnalyzeFetchNce( ExtensibleChip * i_membChip,
STEP_CODE_DATA_STRUCT & i_sc, uint32_t i_mbaPos )
{
#define PRDF_FUNC "[AnalyzeFetchNce] "
int32_t l_rc = SUCCESS;
ExtensibleChip * mbaChip = NULL;
do
{
CenMembufDataBundle * membdb = getMembufDataBundle( i_membChip );
mbaChip = membdb->getMbaChip( i_mbaPos );
if ( NULL == mbaChip )
{
PRDF_ERR( PRDF_FUNC"getMbaChip() returned NULL" );
l_rc = FAIL; break;
}
TargetHandle_t mbaTrgt = mbaChip->GetChipHandle();
CenAddr addr;
l_rc = getCenReadAddr( i_membChip, i_mbaPos, READ_NCE_ADDR, addr );
if ( SUCCESS != l_rc )
{
PRDF_ERR( PRDF_FUNC"getCenReadAddr() failed" );
break;
}
CenRank rank = addr.getRank();
if ( 0x20 > getChipLevel(i_membChip->GetChipHandle()) )
{
// There is a bug in DD1.x where the value of MBSEVR cannot be
// trusted. The workaround is too complicated for its value so
// callout the rank instead.
MemoryMru memmru ( mbaTrgt, rank, MemoryMruData::CALLOUT_RANK );
i_sc.service_data->SetCallout( memmru );
}
else // DD2.0+
{
// Get the failing symbol
const char * reg_str = (0 == i_mbaPos) ? "MBA0_MBSEVR"
: "MBA1_MBSEVR";
SCAN_COMM_REGISTER_CLASS * reg = i_membChip->getRegister(reg_str);
l_rc = reg->Read();
if ( SUCCESS != l_rc )
{
PRDF_ERR( PRDF_FUNC"Read() failed on %s", reg_str );
break;
}
uint8_t galois = reg->GetBitFieldJustified( 40, 8 );
uint8_t mask = reg->GetBitFieldJustified( 32, 8 );
CenSymbol symbol = CenSymbol::fromGalois( mbaTrgt, rank, galois,
mask );
if ( !symbol.isValid() )
{
PRDF_ERR( PRDF_FUNC"Failed to create symbol: galois=0x%02x "
"mask=0x%02x", galois, mask );
break;
}
// Check if this symbol is on any of the spares.
CenSymbol sp0, sp1, ecc;
l_rc = mssGetSteerMux( mbaTrgt, rank, sp0, sp1, ecc );
if ( SUCCESS != l_rc )
{
PRDF_ERR( PRDF_FUNC"mssGetSteerMux() failed. HUID: 0x%08x "
"rank: %d", getHuid(mbaTrgt), rank.getMaster() );
break;
}
if ( (sp0.isValid() && (sp0.getDram() == symbol.getDram())) ||
(sp1.isValid() && (sp1.getDram() == symbol.getDram())) )
{
symbol.setDramSpared();
}
if ( ecc.isValid() && (ecc.getDram() == symbol.getDram()) )
{
symbol.setEccSpared();
}
// Add the DIMM to the callout list
MemoryMru memmru ( mbaTrgt, rank, symbol );
i_sc.service_data->SetCallout( memmru, MRU_MEDA );
// Add to CE table
CenMbaDataBundle * mbadb = getMbaDataBundle( mbaChip );
uint32_t ceTableRc = mbadb->iv_ceTable.addEntry( addr, symbol );
bool doTps = ( CenMbaCeTable::NO_TH_REACHED != ceTableRc );
// Check MNFG thresholds, if needed.
if ( mfgMode() )
{
// Get the MNFG CE thresholds.
uint16_t dramTh, hrTh, dimmTh;
l_rc = getMnfgMemCeTh( mbaChip, rank, dramTh, hrTh, dimmTh );
if ( SUCCESS != l_rc )
{
PRDF_ERR( PRDF_FUNC"getMnfgMemCeTh() failed: rank=m%ds%d",
rank.getMaster(), rank.getSlave() );
break;
}
// Get counts from CE table.
uint32_t dramCount, hrCount, dimmCount;
mbadb->iv_ceTable.getMnfgCounts( addr.getRank(), symbol,
dramCount, hrCount,
dimmCount );
if ( dramTh < dramCount )
{
i_sc.service_data->AddSignatureList( mbaTrgt,
PRDFSIG_MnfgDramCte );
i_sc.service_data->SetServiceCall();
doTps = true;
}
else if ( hrTh < hrCount )
{
i_sc.service_data->AddSignatureList( mbaTrgt,
PRDFSIG_MnfgHrCte );
i_sc.service_data->SetServiceCall();
doTps = true;
}
else if ( dimmTh < dimmCount )
{
i_sc.service_data->AddSignatureList( mbaTrgt,
PRDFSIG_MnfgDimmCte );
i_sc.service_data->SetServiceCall();
doTps = true;
}
else if ( 0 != (CenMbaCeTable::TABLE_FULL & ceTableRc) )
{
i_sc.service_data->AddSignatureList( mbaTrgt,
PRDFSIG_MnfgTableFull);
// The table is full and no other threshold has been met.
// We are in a state where we may never hit a MNFG
// threshold. Callout all memory behind the MBA. Also, since
// the counts are all over the place, there may be a problem
// with the MBA. So call it out as well.
MemoryMru all_mm ( mbaTrgt, rank,
MemoryMruData::CALLOUT_ALL_MEM );
i_sc.service_data->SetCallout( all_mm, MRU_MEDA );
i_sc.service_data->SetCallout( mbaTrgt, MRU_MEDA );
i_sc.service_data->SetServiceCall();
}
else if ( 0 != (CenMbaCeTable::ENTRY_TH_REACHED & ceTableRc) )
{
i_sc.service_data->AddSignatureList( mbaTrgt,
PRDFSIG_MnfgEntryCte );
// There is a single entry threshold and no other threshold
// has been met. This is a potential flooding issue, so make
// the DIMM callout predictive.
i_sc.service_data->SetServiceCall();
}
}
// Initiate a TPS procedure, if needed.
if ( doTps )
{
// If a MNFG threshold has been reached (predictive callout), we
// will still try to start TPS just in case MNFG disables the
// termination policy.
// Will not be able to do TPS during hostboot. Note that we will
// still call handleTdEvent() so we can get the trace statement
// indicating TPS was requested during Hostboot.
l_rc = mbadb->iv_tdCtlr.handleTdEvent( i_sc, rank,
CenMbaTdCtlrCommon::TPS_EVENT );
if ( SUCCESS != l_rc )
{
PRDF_ERR( PRDF_FUNC"handleTdEvent() failed: rank=m%ds%d",
rank.getMaster(), rank.getSlave() );
break;
}
}
}
} while (0);
// Add ECC capture data for FFDC.
if ( NULL != mbaChip )
CenMbaCaptureData::addMemEccData( mbaChip, i_sc );
if ( SUCCESS != l_rc )
{
PRDF_ERR( PRDF_FUNC"Failed: i_membChip=0x%08x i_mbaPos=%d",
i_membChip->GetId(), i_mbaPos );
CalloutUtil::defaultError( i_sc );
}
return SUCCESS; // Intentionally return SUCCESS for this plugin
#undef PRDF_FUNC
}
/**
* @brief MBSECCFIR[0:7] - Fetch Mark Placed Event (MPE).
* @param i_membChip A Centaur chip.
* @param i_sc The step code data struct.
* @param i_mbaPos The MBA position.
* @param i_rank The target rank.
* @return SUCCESS
*/
int32_t AnalyzeFetchMpe( ExtensibleChip * i_membChip,
STEP_CODE_DATA_STRUCT & i_sc,
uint32_t i_mbaPos, uint8_t i_rank )
{
#define PRDF_FUNC "[AnalyzeFetchMpe] "
int32_t l_rc = SUCCESS;
ExtensibleChip * mbaChip = NULL;
do
{
CenMembufDataBundle * membdb = getMembufDataBundle( i_membChip );
mbaChip = membdb->getMbaChip( i_mbaPos );
if ( NULL == mbaChip )
{
PRDF_ERR( PRDF_FUNC"getMbaChip() returned NULL" );
l_rc = FAIL; break;
}
CenMbaDataBundle * mbadb = getMbaDataBundle( mbaChip );
TargetHandle_t mbaTrgt = mbaChip->GetChipHandle();
CenAddr addr;
l_rc = getCenReadAddr( i_membChip, i_mbaPos, READ_MPE_ADDR, addr );
if ( SUCCESS != l_rc )
{
PRDF_ERR( PRDF_FUNC"getCenReadAddr() failed" );
break;
}
// If the address does not match the rank that reported the attention,
// there are multiple MPE attentions and the address was overwritten.
// In this case, add an invalid dummy address to the UE table.
if ( addr.getRank().getMaster() != i_rank )
{
addr = CenAddr( i_rank, 0, 0xffffffff, 0xffffffff, 0xffffffff );
}
mbadb->iv_ueTable.addEntry( UE_TABLE::FETCH_MPE, addr );
// Get the current mark in hardware.
CenRank rank ( addr.getRank() );
CenMark mark;
l_rc = mssGetMarkStore( mbaTrgt, rank, mark );
if ( SUCCESS != l_rc )
{
PRDF_ERR( PRDF_FUNC"mssGetMarkStore() failed");
break;
}
if ( !mark.getCM().isValid() )
{
PRDF_ERR( PRDF_FUNC"FIR bit set but no valid chip mark" );
l_rc = FAIL; break;
}
// Callout the mark.
CalloutUtil::calloutMark( mbaTrgt, rank, mark, i_sc );
// Tell TD controller to handle VCM event.
l_rc = mbadb->iv_tdCtlr.handleTdEvent( i_sc, rank,
CenMbaTdCtlrCommon::VCM_EVENT );
if ( SUCCESS != l_rc )
{
PRDF_ERR( PRDF_FUNC"handleTdEvent() failed." );
break;
}
} while (0);
// Add ECC capture data for FFDC.
if ( NULL != mbaChip )
CenMbaCaptureData::addMemEccData( mbaChip, i_sc );
if ( SUCCESS != l_rc )
{
PRDF_ERR( PRDF_FUNC"Failed: i_membChip=0x%08x i_mbaPos=%d i_rank=%d",
i_membChip->GetId(), i_mbaPos, i_rank );
CalloutUtil::defaultError( i_sc );
}
return SUCCESS; // Intentionally return SUCCESS for this plugin
#undef PRDF_FUNC
}
/**
* @brief Analysis code that is called before the main analyze() function.
* @param i_mbChip A MEMBUF chip.
* @param i_sc Step Code Data structure
* @param o_analyzed TRUE if analysis has been done on this chip
* @return failure or success
*/
int32_t PreAnalysis( ExtensibleChip * i_mbChip, STEP_CODE_DATA_STRUCT & i_sc,
bool & o_analyzed )
{
#define PRDF_FUNC "[Membuf::PreAnalysis] "
int32_t o_rc = SUCCESS;
o_analyzed = false;
// Get memory capture data.
CaptureData & cd = i_sc.service_data->GetCaptureData();
CenMembufDataBundle * mbdb = getMembufDataBundle( i_mbChip );
ExtensibleChip * mcsChip = mbdb->getMcsChip();
if ( NULL != mcsChip )
{
mcsChip->CaptureErrorData( cd, Util::hashString("FirRegs") );
mcsChip->CaptureErrorData( cd, Util::hashString("CerrRegs") );
CenMbaCaptureData::addMemChipletFirRegs( i_mbChip, cd );
}
// Check for a Centaur Checkstop
do
{
// Skip if we're already analyzing a unit checkstop
if ( i_sc.service_data->GetFlag(ServiceDataCollector::UNIT_CS) )
break;
// Skip if we're analyzing a special attention.
// This is a required for a rare scenario when Centaur CS bit comes
// up after attention has called PRD and PRD was still at start of
// analysis.
if ( SPECIAL == i_sc.service_data->GetAttentionType() )
break;
// MCIFIR[31] is not always reliable if the unit CS originated on the
// Centaur. This is due to packets not getting forwarded to the MCS.
// Instead, check for non-zero GLOBAL_CS_FIR.
SCAN_COMM_REGISTER_CLASS * fir = i_mbChip->getRegister("GLOBAL_CS_FIR");
o_rc = fir->Read();
if ( SUCCESS != o_rc )
{
PRDF_ERR( PRDF_FUNC"Failed to read GLOBAL_CS_FIR on 0x%08x",
i_mbChip->GetId() );
break;
}
if ( fir->BitStringIsZero() ) break; // No unit checkstop
// Set Unit checkstop flag
i_sc.service_data->SetFlag(ServiceDataCollector::UNIT_CS);
i_sc.service_data->SetThresholdMaskId(0);
// Set the cause attention type
i_sc.service_data->SetCauseAttentionType(UNIT_CS);
} while (0);
return o_rc;
#undef PRDF_FUNC
}
int32_t cleanupSecondaryFirBits( ExtensibleChip * i_chip,
TYPE i_busType,
uint32_t i_busPos )
{
int32_t l_rc = SUCCESS;
TargetHandle_t mcsTgt = NULL;
TargetHandle_t mbTgt = NULL;
ExtensibleChip * mcsChip = NULL;
ExtensibleChip * mbChip = NULL;
//In case of spare deployed attention for DMI bus, we need to clear
// secondary MBIFIR[10] and MCIFIR[10] bits.
do
{
if ( i_busType == TYPE_MCS )
{
mcsTgt = getConnectedChild( i_chip->GetChipHandle(),
TYPE_MCS,
i_busPos);
if (!mcsTgt) break;
mcsChip = ( ExtensibleChip * )systemPtr->GetChip( mcsTgt );
if (!mcsChip) break;
mbChip = getMcsDataBundle( mcsChip )->getMembChip();
if (!mbChip) break;
mbTgt = mbChip->GetChipHandle();
if (!mbTgt) break;
}
else if ( i_busType == TYPE_MEMBUF )
{
mbTgt = i_chip->GetChipHandle();
if (!mbTgt) break;
mcsChip = getMembufDataBundle( i_chip )->getMcsChip();
if (!mcsChip) break;
mcsTgt = mcsChip->GetChipHandle();
if (!mcsTgt) break;
mbChip = i_chip;
}
else
{
// We only need to clean secondary FIR bits for DMI bus
l_rc = SUCCESS;
break;
}
SCAN_COMM_REGISTER_CLASS * mciAnd = mcsChip->getRegister("MCIFIR_AND");
SCAN_COMM_REGISTER_CLASS * mbiAnd = mbChip->getRegister( "MBIFIR_AND");
mciAnd->setAllBits(); mciAnd->ClearBit(10);
mbiAnd->setAllBits(); mbiAnd->ClearBit(10);
l_rc = mciAnd->Write();
l_rc |= mbiAnd->Write();
if ( SUCCESS != l_rc )
{
PRDF_ERR( "[cleanupSecondaryFirBits] Write() failed on "
"MCIFIR/MBIFIR: MCS=0x%08x MEMB=0x%08x",
mcsChip->GetId(), mbChip->GetId() );
break;
}
} while (0);
return l_rc;
}
