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|
/* IBM_PROLOG_BEGIN_TAG */
/* This is an automatically generated prolog. */
/* */
/* $Source: src/usr/hdat/hdatmsarea.C $ */
/* */
/* OpenPOWER HostBoot Project */
/* */
/* Contributors Listed Below - COPYRIGHT 2016,2017 */
/* [+] 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 */
/**
* @file hdatmsarea.C
*
* @brief This file contains the implementation of the HdatMsArea class.
*
*/
/*----------------------------------------------------------------------------*/
/* Includes */
/*----------------------------------------------------------------------------*/
#include <stdlib.h> // malloc & free
#include <hdat/hdat.H> // debug compile control variables
#include "hdatmsarea.H" // HdatMsArea class definition
#include "hdatutil.H" // utility functions
#include "hdatmsvpd.H"
#include <stdio.h>
namespace HDAT
{
/*----------------------------------------------------------------------------*/
/* Global variables */
/*----------------------------------------------------------------------------*/
uint32_t HdatMsArea::cv_actualCnt;
static vpdData cvpdData[] =
{
// { MVPD::VINI, MVPD::RT },
{ MVPD::VINI, MVPD::DR },
{ MVPD::VINI, MVPD::FN },
{ MVPD::VINI, MVPD::PN },
{ MVPD::VINI, MVPD::SN },
{ MVPD::VINI, MVPD::CC },
// { MVPD::VINI, MVPD::PR },
//{ MVPD::VINI, MVPD::SZ },
{ MVPD::VINI, MVPD::HE },
{ MVPD::VINI, MVPD::CT },
{ MVPD::VINI, MVPD::HW },
// { MVPD::VINI, MVPD::B3 },
// { MVPD::VINI, MVPD::B4 },
// { MVPD::VINI, MVPD::B7 },
};
const HdatKeywordInfo l_cvpdKeywords[] =
{
{ CVPD::DR, "DR" },
{ CVPD::FN, "FN" },
{ CVPD::PN, "PN" },
{ CVPD::SN, "SN" },
{ CVPD::CC, "CC" },
{ CVPD::HE, "HE" },
{ CVPD::CT, "CT" },
{ CVPD::HW, "HW" },
{ CVPD::PF, "PF" },
};
/** @brief See the prologue in hdatmsarea.H
*/
HdatMsArea::HdatMsArea(errlHndl_t &o_errlHndl,
TARGETING::Target * i_target,
uint16_t i_msAreaId,
uint32_t i_ramCnt,
uint32_t i_chipEcCnt,
uint32_t i_addrRngCnt,
uint32_t i_resourceId,
uint32_t i_slcaIdx,
uint32_t i_kwdSize,
char *&i_kwd)
: HdatHdif(o_errlHndl,HDAT_MSAREA_STRUCT_NAME,HDAT_MS_AREA_LAST,cv_actualCnt++,
HDAT_MS_AREA_CHILD_LAST,HDAT_MS_AREA_VERSION),
iv_kwdSize(i_kwdSize),
iv_maxAddrRngCnt(HDAT_MAX_ADDR_RNG_ENTRIES), iv_maxEcCnt(HDAT_MAX_EC_ENTRIES),
iv_maxRamCnt(i_ramCnt), iv_actRamCnt(0), iv_maxRamObjSize(0), iv_kwd(NULL),
iv_ramPadReq(false),iv_addrRange(NULL), iv_ecLvl(NULL), iv_ramPtrs(NULL)
{
HDAT_ENTER( );
uint32_t l_slcaIdx = 0;
iv_msaHostI2cCnt = 0;
iv_msaHostI2cSize = 0;
iv_msaI2cDataPtr = NULL;
o_errlHndl = NULL;
iv_fru.hdatResourceId = i_resourceId;
memset(&iv_msId, 0x00, sizeof(hdatMsAreaId_t));
memset(&iv_msSize, 0x00, sizeof(hdatMsAreaSize_t));
memset(&iv_aff, 0x00, sizeof(hdatMsAreaAffinity_t));
iv_msId.hdatMsAreaId = i_msAreaId;
iv_addrRngArrayHdr.hdatOffset = sizeof(hdatHDIFDataArray_t);
iv_addrRngArrayHdr.hdatArrayCnt = 0;
iv_addrRngArrayHdr.hdatAllocSize = sizeof(hdatMsAreaAddrRange_t);
iv_addrRngArrayHdr.hdatActSize = sizeof(hdatMsAreaAddrRange_t);
iv_ecArrayHdr.hdatOffset = sizeof(hdatHDIFDataArray_t);
iv_ecArrayHdr.hdatArrayCnt = 0;
iv_ecArrayHdr.hdatAllocSize = sizeof(hdatMsAreaEcLvl_t);
iv_ecArrayHdr.hdatActSize = sizeof(hdatMsAreaEcLvl_t);
l_slcaIdx = i_slcaIdx;
// If the ASCII keyword data and related info has been passed to us as a
// parm, use it and avoid calling into svpd. This is an IPL performance
// improvement since all mainstore areas for an MCM will have the same
// resource id and thus the same keyword VPD.
if (i_kwdSize > 0)
{
l_slcaIdx = i_slcaIdx;
iv_kwd = new char[i_kwdSize];
memcpy(iv_kwd, i_kwd, i_kwdSize);
}
else
{
// Get the SLCA index and ASCII keyword for this resource id
uint32_t l_num = sizeof(cvpdData)/sizeof(cvpdData[0]);
size_t theSize[l_num];
hdatGetAsciiKwdForMvpd(i_target,iv_kwdSize,iv_kwd,cvpdData,
l_num,theSize);
do
{
char *o_fmtKwd;
uint32_t o_fmtkwdSize;
o_errlHndl = hdatformatAsciiKwd(cvpdData , l_num , theSize, iv_kwd,
iv_kwdSize, o_fmtKwd, o_fmtkwdSize, l_cvpdKeywords);
if( o_fmtKwd != NULL )
{
delete[] iv_kwd;
//padding extra 8 bytes to keep data sync as FSP
iv_kwd = new char [o_fmtkwdSize + 8];
memcpy(iv_kwd,o_fmtKwd,o_fmtkwdSize);
iv_kwdSize = o_fmtkwdSize + 8;
delete[] o_fmtKwd;
}
}while(0);
}
// Allocate space for the address range array
if (NULL == o_errlHndl)
{
iv_addrRange = new hdatMsAreaAddrRange_t[iv_maxAddrRngCnt];
memset(iv_addrRange,0,
(sizeof(hdatMsAreaAddrRange_t) * iv_maxAddrRngCnt));
}
// Allocate space for the EC level array
if (NULL == o_errlHndl)
{
iv_fru.hdatSlcaIdx = l_slcaIdx;
iv_ecLvl = new hdatMsAreaEcLvl_t[iv_maxEcCnt];
}
// Allocate space for the RAM entries
if (NULL == o_errlHndl)
{
iv_ramPtrs = new HdatRam*[i_ramCnt];
}
HDAT_EXIT();
return;
}
/** @brief See the prologue in hdatmsarea.H
*/
HdatMsArea::~HdatMsArea()
{
HDAT_ENTER( );
uint32_t l_cnt;
HdatRam *l_ramObj, **l_curPtr;
// Delete RAM Objects
l_curPtr = iv_ramPtrs;
for (l_cnt = 0; l_cnt < iv_actRamCnt; l_cnt++)
{
l_ramObj = *l_curPtr;
delete l_ramObj;
l_curPtr = reinterpret_cast<HdatRam **>(reinterpret_cast<char*>(l_curPtr)
+ sizeof(HdatRam *));
}
delete[] iv_kwd;
delete[] iv_addrRange;
delete[] iv_ecLvl;
delete [] iv_ramPtrs;
HDAT_EXIT();
return;
}
/** @brief See the prologue in hdatmsarea.H
*/
void HdatMsArea::setParentType(uint16_t i_type)
{
iv_msId.hdatMsAreaParentType = i_type;
return;
}
/** @brief See the prologue in hdatmsarea.H
*/
void HdatMsArea::setStatus(uint16_t i_status)
{
iv_msId.hdatMsAreaStatus = i_status;
return;
}
/** @brief See the prologue in hdatmsarea.H
*/
void HdatMsArea::setInterleavedId(uint16_t i_id)
{
iv_msId.hdatInterleavedId = i_id;
return;
}
/** @brief See the prologue in hdatmsarea.H
*/
void HdatMsArea::setSize(uint32_t i_size)
{
iv_msSize.hdatReserved1 = 0;
iv_msSize.hdatMsAreaSize = i_size;
return;
}
/** @brief See the prologue in hdatmsarea.H
*/
void HdatMsArea::setModuleId(uint32_t i_moduleId)
{
iv_aff.hdatMsAreaModuleId = i_moduleId;
return;
}
/** @brief See the prologue in hdatmsarea.H
*/
void HdatMsArea::setAffinityDomain(uint32_t i_affinityDomain)
{
iv_aff.hdatMsAffinityDomain = i_affinityDomain;
return;
}
/** @brief See the prologue in hdatmsarea.H
*/
void HdatMsArea::getKwdInfo(uint32_t &o_resourceId,
uint32_t &o_slcaIdx,
uint32_t &o_kwdSize,
char *&o_kwd)
{
o_resourceId = iv_fru.hdatResourceId;
o_slcaIdx = iv_fru.hdatSlcaIdx;
o_kwdSize = iv_kwdSize;
o_kwd = iv_kwd;
return;
}
/** @brief See the prologue in hdatmsarea.H
*/
errlHndl_t HdatMsArea::addAddrRange(hdatMsAddr_t &i_start,
hdatMsAddr_t &i_end,
uint32_t i_procChipId,
bool i_rangeIsMirrorable,
uint8_t i_mirroringAlgorithm,
hdatMsAddr_t &i_startMirrAddr)
{
HDAT_ENTER();
errlHndl_t l_errlHndl = NULL;
hdatMsAreaAddrRange_t *l_addr;
if (iv_addrRngArrayHdr.hdatArrayCnt < iv_maxAddrRngCnt)
{
l_addr = reinterpret_cast<hdatMsAreaAddrRange_t*>(
reinterpret_cast<char*>(iv_addrRange) + iv_addrRngArrayHdr.hdatArrayCnt*
sizeof(hdatMsAreaAddrRange_t));
l_addr->hdatMsAreaStrAddr = i_start;
l_addr->hdatMsAreaEndAddr = i_end;
l_addr->hatMsAreaProcChipId = i_procChipId;
l_addr->hdatSMMAttributes.hdatRangeIsMirrorable =
i_rangeIsMirrorable ? 1 : 0;
l_addr->hdatSMMAttributes.hdatMirroringAlgorithm = i_mirroringAlgorithm;
l_addr->hdatStartMirrAddr = i_startMirrAddr;
iv_addrRngArrayHdr.hdatArrayCnt++;
}
else
{
/*@
* @errortype
* @refcode LIC_REFCODE
* @subsys EPUB_FIRMWARE_SP
* @reasoncode RC_ERC_MAX_EXCEEDED
* @moduleid MOD_ADD_ADDR_RANGE
* @userdata1 current number of array entries
* @userdata2 maximum number of array entries
* @userdata3 ID number of mainstore area
* @userdata4 none
* @devdesc Failed trying to add another entry to a mainstore area
* address range array
*/
hdatBldErrLog(l_errlHndl,
MOD_ADD_ADDR_RANGE, // SRC module ID
RC_ERC_MAX_EXCEEDED, // SRC extended reference code
iv_addrRngArrayHdr.hdatArrayCnt, // SRC hex word 1
iv_maxAddrRngCnt, // SRC hex word 2
iv_msId.hdatMsAreaId); // SRC hex word 3
}
HDAT_EXIT();
return l_errlHndl;
}
/** @brief See the prologue in hdatmsarea.H
*/
errlHndl_t HdatMsArea::addEcEntry(uint32_t i_manfId,
uint32_t i_ecLvl)
{
HDAT_ENTER();
errlHndl_t l_errlHndl = NULL;
hdatMsAreaEcLvl_t *l_ec;
if (iv_ecArrayHdr.hdatArrayCnt < iv_maxEcCnt)
{
l_ec = reinterpret_cast<hdatMsAreaEcLvl_t*>(reinterpret_cast<char*>
(iv_ecLvl) + iv_ecArrayHdr.hdatArrayCnt * sizeof(hdatMsAreaEcLvl_t));
l_ec->hdatChipManfId = i_manfId;
l_ec->hdatChipEcLvl = i_ecLvl;
iv_ecArrayHdr.hdatArrayCnt++;
}
HDAT_EXIT();
return l_errlHndl;
}
/** @brief See the prologue in hdatmsarea.H
*/
void HdatMsArea::setMsaI2cInfo(
std::vector<hdatMsAreaHI2cData_t> &i_I2cDevEntries )
{
HDAT_ENTER();
iv_msaI2cHdr.hdatOffset = 0x0010; // this is just header of 4 words. arrays start at 0x0010
iv_msaI2cHdr.hdatArrayCnt = i_I2cDevEntries.size();
iv_msaI2cHdr.hdatAllocSize = sizeof(hdatMsAreaHI2cData_t);
iv_msaI2cHdr.hdatActSize = sizeof(hdatMsAreaHI2cData_t);
iv_msaHostI2cCnt = i_I2cDevEntries.size();
iv_msaHostI2cSize = sizeof(hdatHDIFDataArray_t) +
(sizeof(hdatMsAreaHI2cData_t) * iv_msaHostI2cCnt);
HDAT_INF("iv_msaHostI2cCnt=%d, iv_msaHostI2cSize=%d",
iv_msaHostI2cCnt, iv_msaHostI2cSize);
if ( i_I2cDevEntries.size() != 0 )
{
//copy from vector to array
std::copy(i_I2cDevEntries.begin(),i_I2cDevEntries.end(),
iv_msaI2cDataPtr);
}
else
{
HDAT_INF("Empty Host I2C device info vector : Ms Area Id=%d, Size=%d",
iv_msId.hdatMsAreaId, i_I2cDevEntries.size());
}
HDAT_EXIT();
}
/** @brief See the prologue in hdatmsarea.H
*/
errlHndl_t HdatMsArea::addRam(HdatRam &i_ram)
{
HDAT_ENTER();
errlHndl_t l_errlHndl = NULL;
HdatRam **l_arrayEntry;
uint32_t l_ramSize;
if (iv_actRamCnt < iv_maxRamCnt)
{
l_arrayEntry = reinterpret_cast<HdatRam**>(reinterpret_cast<char*>
(iv_ramPtrs) + iv_actRamCnt * sizeof(HdatRam *));
*l_arrayEntry = &i_ram;
//Determine if the size of this RAM is larger than any other RAM objects
// associated with this mainstore area
l_ramSize = i_ram.size();
if (l_ramSize != iv_maxRamObjSize)
{
// If not the first RAM object, then we have to pad some shorter
// RAM object(s)
if (iv_maxRamObjSize != 0)
{
iv_ramPadReq = true;
}
if (l_ramSize > iv_maxRamObjSize)
{
iv_maxRamObjSize = l_ramSize;
}
}
iv_actRamCnt++;
}
else
{
/*@
* @errortype
* @refcode LIC_REFCODE
* @subsys EPUB_FIRMWARE_SP
* @reasoncode RC_ERC_MAX_EXCEEDED
* @moduleid MOD_ADD_RAM
* @userdata1 current number of array entries
* @userdata2 maximum number of array entries
* @userdata3 ID number of mainstore area
* @userdata4 none
* @devdesc Failed trying to add another entry to a mainstore area
* RAM array
*/
HDAT_INF("Failed trying to add another entry to a mainstore area RAM "
"array %d",iv_actRamCnt);
hdatBldErrLog(l_errlHndl,
MOD_ADD_RAM, // SRC module ID
RC_ERC_MAX_EXCEEDED, // SRC extended reference code
iv_actRamCnt, // SRC hex word 1
iv_maxRamCnt, // SRC hex word 2
iv_msId.hdatMsAreaId); // SRC hex word 3
}
HDAT_EXIT();
return l_errlHndl;
}
/** @brief See the prologue in hdatmsarea.H
*/
uint32_t HdatMsArea::ramObjSizes()
{
HDAT_ENTER();
uint32_t l_size, l_cnt;
HdatRam *l_ramObj;
l_size = 0;
// Process the RAM objects
for (l_cnt = 0; l_cnt < iv_actRamCnt; l_cnt++)
{
l_ramObj = *(reinterpret_cast<HdatRam **>(reinterpret_cast<char*>
(iv_ramPtrs) + l_cnt * sizeof(HdatRam *)));
l_size += l_ramObj->size();
}
HDAT_EXIT();
return l_size;
}
/** @brief See the prologue in hdatmsarea.H
*/
void HdatMsArea::finalizeObjSize()
{
HDAT_ENTER();
uint32_t l_idx;
HdatRam **l_ramEntry;
// Update the base class internal data pointers
// When the data is written to the file by commit(), it must be done in the
// same order as these addData() calls
this->addData(HDAT_MS_AREA_FRU_ID, sizeof(hdatFruId_t));
this->addData(HDAT_MS_AREA_KWD, iv_kwdSize);
this->addData(HDAT_MS_AREA_ID, sizeof(hdatMsAreaId_t));
this->addData(HDAT_MS_AREA_SIZE, sizeof(hdatMsAreaSize_t));
this->addData(HDAT_MS_AREA_ADDR_RNG, sizeof(hdatHDIFDataArray_t) +
iv_maxAddrRngCnt * sizeof(hdatMsAreaAddrRange_t));
this->addData(HDAT_MS_AREA_AFF, sizeof(hdatMsAreaAffinity_t));
this->addData(HDAT_MS_AREA_EC_ARRAY, sizeof(hdatHDIFDataArray_t) +
iv_maxEcCnt * sizeof(hdatMsAreaEcLvl_t));
this->addData(HDAT_MS_AREA_HOST_I2C, iv_msaHostI2cSize);
this->align();
// If we have RAM objects of different sizes, the smaller ones have to be
// padded to the size of the largest one so that PHYP can traverse through
// the RAM objects as elements of an array.
if (iv_ramPadReq)
{
for (l_idx = 0; l_idx < iv_actRamCnt; l_idx++)
{
l_ramEntry = (reinterpret_cast<HdatRam **>(reinterpret_cast<char*>
(iv_ramPtrs) + l_idx * sizeof(HdatRam *)));
if (iv_maxRamObjSize > (*l_ramEntry)->size())
{
(*l_ramEntry)->maxSiblingSize(iv_maxRamObjSize);
}
}
}
// Update the base class for children that have been added
for (l_idx = 0; l_idx < iv_actRamCnt; l_idx++)
{
l_ramEntry = (reinterpret_cast<HdatRam **>(reinterpret_cast<char*>
(iv_ramPtrs) + l_idx * sizeof(HdatRam *)));
this->addChild(HDAT_MS_AREA_RAM_AREAS, (*l_ramEntry)->size(), 1);
// 1st parm is 0 based
}
HDAT_EXIT();
return;
}
/** @brief See the prologue in hdatmsarea.H
*/
uint32_t HdatMsArea::getMsAreaSize()
{
uint32_t l_size = 0;
// Start committing the base class data
l_size += this->getSize();
// Write the various pieces of data from this derived class
l_size += sizeof(hdatFruId_t);
if ( iv_kwdSize > 0)
{
l_size += iv_kwdSize;
}
l_size += sizeof(hdatMsAreaId_t);
l_size += sizeof(hdatMsAreaSize_t);
l_size += sizeof(hdatHDIFDataArray_t);
l_size += (iv_maxAddrRngCnt * sizeof(hdatMsAreaAddrRange_t));
l_size += sizeof(hdatMsAreaAffinity_t);
l_size += sizeof(hdatHDIFDataArray_t);
l_size += (iv_maxEcCnt * sizeof(hdatMsAreaEcLvl_t));
l_size += this->endCommitSize();
return l_size;
}
/** @brief See the prologue in hdatmsarea.H
*/
uint32_t HdatMsArea::getRamAreaSize()
{
uint32_t l_size = 0, l_cnt = 0;
HdatRam *l_ramObj;
// Write the RAM structures
if (iv_actRamCnt > 0)
{
l_cnt = 0;
while (l_cnt < iv_actRamCnt)
{
l_ramObj = *(reinterpret_cast<HdatRam **>(reinterpret_cast<char*>
(iv_ramPtrs) + l_cnt * sizeof(HdatRam *)));
l_size += l_ramObj->getRamSize();
l_cnt++;
}
}
return l_size;
}
/** @brief See the prologue in hdatmsarea.H
*/
void HdatMsArea::commit(UtilMem &i_data)
{
// Start committing the base class data
this->startCommit(i_data);
i_data.write(&iv_fru,sizeof(hdatFruId_t));
if (iv_kwdSize > 0)
{
i_data.write(iv_kwd,iv_kwdSize);
}
i_data.write(&iv_msId,sizeof(hdatMsAreaId_t));
i_data.write(&iv_msSize, sizeof(hdatMsAreaSize_t));
i_data.write(&iv_addrRngArrayHdr,sizeof(hdatHDIFDataArray_t));
i_data.write(iv_addrRange,iv_maxAddrRngCnt * sizeof(hdatMsAreaAddrRange_t));
i_data.write(&iv_aff, sizeof(hdatMsAreaAffinity_t));
i_data.write(&iv_ecArrayHdr, sizeof(hdatHDIFDataArray_t));
i_data.write(iv_ecLvl,iv_maxEcCnt * sizeof(hdatMsAreaEcLvl_t));
i_data.write(&iv_msaI2cHdr, sizeof(hdatHDIFDataArray_t));
if (NULL != iv_msaI2cDataPtr)
{
i_data.write(iv_msaI2cDataPtr,
(iv_msaHostI2cSize - sizeof(hdatHDIFDataArray_t)));
}
this->endCommit(i_data);
}
/** @brief See the prologue in hdatmsarea.H
*/
void HdatMsArea::commitRamAreas(UtilMem &i_data)
{
uint32_t l_cnt;
HdatRam *l_ramObj;
// Write the RAM structures
if (iv_actRamCnt > 0)
{
l_cnt = 0;
while (l_cnt < iv_actRamCnt)
{
l_ramObj = *(reinterpret_cast<HdatRam **>(reinterpret_cast<char*>
(iv_ramPtrs) + l_cnt * sizeof(HdatRam *)));
l_ramObj->commit(i_data);
l_cnt++;
}
}
}
/** @brief See the prologue in hdatmsarea.H
*/
void HdatMsArea::prt()
{
uint32_t l_cnt;
hdatMsAreaEcLvl_t *l_ec;
hdatMsAreaAddrRange_t *l_addr;
HdatRam *l_ramObj;
HDAT_INF(" **** HdatMsArea start ****");
HDAT_INF(" cv_actualCnt = %u", cv_actualCnt);
HDAT_INF(" iv_kwdSize = %u", iv_kwdSize);
HDAT_INF(" iv_maxAddrRngCnt = %u", iv_maxAddrRngCnt);
HDAT_INF(" iv_maxEcCnt = %u", iv_maxEcCnt);
HDAT_INF(" iv_maxRamCnt = %u", iv_maxRamCnt);
HDAT_INF(" iv_actRamCnt = %u", iv_actRamCnt);
this->print();
//hdatPrintFruId(&iv_fru);
hdatPrintKwd(iv_kwd, iv_kwdSize);
HDAT_INF(" **hdatMsAreaId_t**");
HDAT_INF(" hdatMsAreaId = %u", iv_msId.hdatMsAreaId);
HDAT_INF(" hdatMsAreaParentType = %u", iv_msId.hdatMsAreaParentType);
HDAT_INF(" hdatMsAreaStatus %u", iv_msId.hdatMsAreaStatus);
HDAT_INF(" **hdatMsAreaSize_t**");
HDAT_INF(" hdatMsAreaSize = %u", iv_msSize.hdatMsAreaSize);
HDAT_INF(" **hdatMsAreaAddrRange_t**");
hdatPrintHdrs(NULL, NULL, &iv_addrRngArrayHdr, NULL);
l_addr = iv_addrRange;
for (l_cnt = 0; l_cnt < iv_ecArrayHdr.hdatArrayCnt; l_cnt++)
{
HDAT_INF(" hdatMsAreaStrAddr = 0X %08X %08X ",
l_addr->hdatMsAreaStrAddr.hi,
l_addr->hdatMsAreaStrAddr.lo);
HDAT_INF(" hdatMsAreaEndAddr = 0X %08X %08X ",
l_addr->hdatMsAreaEndAddr.hi,
l_addr->hdatMsAreaEndAddr.lo);
HDAT_INF(" hatMsAreaProcChipId = %u", l_addr->hatMsAreaProcChipId);
HDAT_INF(" hdatSMMAttributes.hdatRangeIsMirrorable = %u",
l_addr->hdatSMMAttributes.hdatRangeIsMirrorable);
HDAT_INF(" hdatSMMAttributes.hdatMirroringAlgorithm = %u",
l_addr->hdatSMMAttributes.hdatMirroringAlgorithm);
HDAT_INF(" hdatStartMirrAddr = 0X %08X %08X ",
l_addr->hdatStartMirrAddr.hi, l_addr->hdatStartMirrAddr.lo);
l_addr++;
l_cnt++;
}
HDAT_INF("");
HDAT_INF(" **hdatMsAreaAffinity_t**");
HDAT_INF(" hdatMsAreaModuleId = %u", iv_aff.hdatMsAreaModuleId);
HDAT_INF(" hdatMsAffinityDomain = %u", iv_aff.hdatMsAffinityDomain);
HDAT_INF(" **hdatMsAreaEcLvl_t**");
hdatPrintHdrs(NULL, NULL, &iv_ecArrayHdr, NULL);
l_ec = iv_ecLvl;
for (l_cnt = 0; l_cnt < iv_ecArrayHdr.hdatArrayCnt; l_cnt++)
{
HDAT_INF(" hdatChipManfId = %u", l_ec->hdatChipManfId);
HDAT_INF(" hdatChipEcLvl = %u", l_ec->hdatChipEcLvl);
l_ec++;
}
HDAT_INF(" **** HdatMsArea end ****");
// Write the RAM structures
if (iv_actRamCnt > 0)
{
HDAT_INF(" **associated RAM objects**");
for(l_cnt = 0; l_cnt < iv_actRamCnt; l_cnt++)
{
l_ramObj = *(HdatRam **)((char *)iv_ramPtrs + l_cnt
* sizeof(HdatRam *));
l_ramObj->prt();
}
}
return;
}
}
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