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targetservicestart.C
executable file
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targetservicestart.C
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/* IBM_PROLOG_BEGIN_TAG */
/* This is an automatically generated prolog. */
/* */
/* $Source: src/usr/targeting/targetservicestart.C $ */
/* */
/* OpenPOWER HostBoot Project */
/* */
/* Contributors Listed Below - COPYRIGHT 2012,2019 */
/* [+] Google Inc. */
/* [+] 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 targeting/targetservicestart.C
*
* @brief Hostboot entry point for target service
*/
//******************************************************************************
// Includes
//******************************************************************************
// STD
#include <stdio.h>
#include <stdlib.h>
#include <limits.h>
// Other components
#include <sys/misc.h>
#include <sys/mm.h>
#include <sys/task.h>
#include <sys/sync.h>
#include <arch/ppc.H>
#include <targeting/common/trace.H>
#include <targeting/adapters/assertadapter.H>
#include <targeting/adapters/types.H>
#include <initservice/taskargs.H>
#include <util/utilmbox_scratch.H>
#include <util/align.H>
// This component
#include <targeting/common/targetservice.H>
#include <targeting/attrrp.H>
#include <targeting/targplatutil.H>
// Others
#include <errl/errlentry.H>
#include <errl/errlmanager.H>
#include <devicefw/userif.H>
#include <config.h>
#include <initservice/initserviceif.H>
#include <util/misc.H>
#include <util/utilrsvdmem.H>
#include <kernel/bltohbdatamgr.H>
#include <map>
#include <arch/memorymap.H>
#include <lpc/lpcif.H>
#include <xscom/xscomif.H>
#include <bootloader/bootloaderif.H>
#include <sbeio/sbeioif.H>
#include <sys/mm.h>
#include "../runtime/hdatstructs.H"
#include <console/consoleif.H>
#ifdef CONFIG_BMC_IPMI
#include <ipmi/ipmiif.H>
#endif
#ifdef CONFIG_DRTM
#include <secureboot/drtm.H>
#endif
#include <targeting/common/associationmanager.H>
using namespace INITSERVICE::SPLESS;
//******************************************************************************
// targetService
//******************************************************************************
namespace TARGETING
{
#define TARG_NAMESPACE "TARGETING::"
#define TARG_LOC TARG_NAMESPACE TARG_CLASS TARG_FN ": "
//******************************************************************************
// _start
//******************************************************************************
#define TARG_CLASS ""
/*
* @brief Initialize any attributes that need to be set early on
*/
static void initializeAttributes(TargetService& i_targetService,
bool i_isMpipl,
bool i_istepMode,
ATTR_MASTER_MBOX_SCRATCH_type& i_masterScratch);
/**
* @brief Check that at least one processor of our cpu type is being targeted
*/
static void checkProcessorTargeting(TargetService& i_targetService);
/**
* @brief Compute any values that might change based on a remap of memory
* @param[in] Pointer to targeting service
*/
static void adjustMemoryMap(TargetService& i_targetService);
/**
* @brief Entry point for initialization service to initialize the targeting
* code
*
* @param[in] io_pError
* Error log handle; returns NULL on success, !NULL otherwise
*
* @note: Link register is configured to automatically invoke task_end() when
* this routine returns
*/
static void initTargeting(errlHndl_t& io_pError)
{
#define TARG_FN "initTargeting(errlHndl_t& io_pError)"
TARG_ENTER();
//Need to stash away the master mbox regs as they will
//be overwritten
bool l_isMpipl = false;
bool l_isIstepMode = false;
ATTR_MASTER_MBOX_SCRATCH_type l_scratch = {0,0,0,0,0,0,0,0};
for(size_t i=0; i< sizeof(l_scratch)/sizeof(l_scratch[0]); i++)
{
l_scratch[i] =
Util::readScratchReg(MBOX_SCRATCH_REG1+i);
}
// Check mbox scratch reg 3 for IPL boot options
// Specifically istep mode (bit 0) and MPIPL (bit 2)
INITSERVICE::SPLESS::MboxScratch3_t l_scratch3;
l_scratch3.data32 = l_scratch[SCRATCH_3];
if(l_scratch3.isMpipl)
{
TARG_INF("We are running MPIPL mode");
l_isMpipl = true;
#ifdef CONFIG_SUPPORT_PARTIAL_CACHE
//If in partial cache mode need to extend to full mem
//Since we are in MPIPL we know that memory is up and running
//in order to avoid burning through all of our memory pages
//during the attrrp init, which is when we copy attributes from
//the prev IPL into PNOR, we expand out to full cache right now
//in activate_threads we will expand out to MM_EXTEND_REAL_MEMORY
mm_extend(MM_EXTEND_FULL_CACHE);
#endif
}
if(l_scratch3.istepMode)
{
l_isIstepMode = true;
}
if(l_scratch3.overrideSecurity)
{
TARG_INF("WARNING: External tool asked master proc to disable "
"security.");
}
if(l_scratch3.allowAttrOverrides)
{
TARG_INF("WARNING: External tool asked master proc to allow "
"attribute overrides even in secure mode.");
}
#ifndef CONFIG_SUPPORT_PARTIAL_CACHE
//To prevent thrashing or "out of memory' errors on richly
//configured systems, always extend into full cache prior
//to loading ATTRs
mm_extend(MM_EXTEND_FULL_CACHE);
#endif
AttrRP::init(io_pError, l_isMpipl);
if (io_pError == NULL)
{
TargetService& l_targetService = targetService();
(void)l_targetService.init();
if(l_isMpipl)
{
// Open the permissions to be able to reset the links between
// sys <-> nodeN established during runtime.
io_pError = l_targetService.modifyReadOnlyPagePermissions(true);
if(io_pError)
{
auto l_plid = io_pError->plid();
errlCommit(io_pError, TARG_COMP_ID);
INITSERVICE::doShutdown(l_plid, true);
}
io_pError = TARGETING::AssociationManager::
reconnectSyAndNodeTargets();
if(io_pError)
{
auto l_plid = io_pError->plid();
errlCommit(io_pError, TARG_COMP_ID);
INITSERVICE::doShutdown(l_plid, true);
}
}
initializeAttributes(l_targetService, l_isMpipl, l_isIstepMode,
l_scratch);
uint32_t l_peerTargetsAdjusted = 0;
uint32_t l_numberMutexAttrsReset = 0;
if(l_isMpipl)
{
for( auto targ_iter = l_targetService.begin();
targ_iter != l_targetService.end();
targ_iter++)
{
const Target* l_pTarget = *targ_iter;
// Ensure all mutex attributes are setup correctly for MPIPL
// Check if there any mutex attributes
// we need to reset on this target
l_numberMutexAttrsReset +=
l_targetService.resetMutexAttributes(l_pTarget);
// Update any peer target addresses if necessary
// updatePeerTargets will write to read-only attribute pages.
// To get around vmm fails we need to allow writes to readonly
// memory for the duration of this loop (unlocking is done
// above).
if(l_targetService.updatePeerTarget(l_pTarget))
{
l_peerTargetsAdjusted++;
}
}
// Now that the loop is complete we can re-apply
// the read only permissions to the read only attr pages
l_targetService.modifyReadOnlyPagePermissions(false);
TARG_INF("Number of peer target addresses adjusted: %d",
l_peerTargetsAdjusted);
TARG_INF("Number of mutex attributes reset: %d",
l_numberMutexAttrsReset);
}
else
{
for( auto targ_iter = l_targetService.begin();
targ_iter != l_targetService.end();
targ_iter++)
{
const Target* l_pTarget = *targ_iter;
// Ensure all mutex attributes are setup correctly for IPL
// Recursive Mutexes need to be setup since they are defaulted
// to all zero.
// Check if there any mutex attributes
// we need to reset on this target
l_targetService.resetMutexAttributes(l_pTarget);
}
}
checkProcessorTargeting(l_targetService);
// Print out top-level model value from loaded targeting values.
// @TODO RTC:88056 Make the model printed more meaniful
Target* l_pTopLevel = NULL;
l_targetService.getTopLevelTarget(l_pTopLevel);
ATTR_MODEL_type l_model = MODEL_NA;
if (l_pTopLevel->tryGetAttr<ATTR_MODEL>(l_model)) {
TARG_INF("Initialized targeting for model: %s",
l_pTopLevel->getAttrAsString<ATTR_MODEL>());
}
#ifdef CONFIG_DRTM
const INITSERVICE::SPLESS::MboxScratch7_t scratch7 =
{.data32 = l_scratch[SCRATCH_7] };
const INITSERVICE::SPLESS::MboxScratch8_t scratch8 =
{.data32 = l_scratch[SCRATCH_8] };
errlHndl_t pError = SECUREBOOT::DRTM::discoverDrtmState(
scratch7,scratch8);
if(pError)
{
auto plid = pError->plid();
errlCommit(pError,SECURE_COMP_ID);
// TODO: RTC 167205: Better GA error handling
INITSERVICE::doShutdown(plid, true);
}
#endif
// Handle possibility of Attribute Overrides allowed in secure mode
bool l_allow_attr_overrides =
g_BlToHbDataManager.getAllowAttrOverrides();
if (l_allow_attr_overrides)
{
TARG_INF("Allow Attribute Overrides In Secure Mode: %d",
l_allow_attr_overrides);
l_pTopLevel->setAttr<
TARGETING::ATTR_ALLOW_ATTR_OVERRIDES_IN_SECURE_MODE>(
l_allow_attr_overrides);
}
else
{
// Hardcode to zero to be safe
l_pTopLevel->setAttr<
TARGETING::ATTR_ALLOW_ATTR_OVERRIDES_IN_SECURE_MODE>(0x0);
}
// No error module loaded in VPO to save load time
#ifndef CONFIG_VPO_COMPILE
// call ErrlManager function - tell him that TARG is ready!
ERRORLOG::ErrlManager::errlResourceReady(ERRORLOG::TARG);
#endif
// set global that TARG is ready
Util::setIsTargetingLoaded();
#ifdef CONFIG_BMC_IPMI
/* Break IPMI's dependency on targeting by setting buffer size here */
l_pTopLevel->setAttr<TARGETING::ATTR_IPMI_MAX_BUFFER_SIZE>
(IPMI::max_buffer());
#endif
}
TARG_EXIT();
#undef TARG_FN
}
/**
* @brief Create _start entry point using task entry macro and vector to
* initTargeting function
*/
TASK_ENTRY_MACRO(initTargeting);
/**
* @brief Check that at least one processor of our cpu type is being targeted
*/
static void checkProcessorTargeting(TargetService& i_targetService)
{
#define TARG_FN "checkProcessorTargeting()"
TARG_ENTER();
PredicateCTM l_procChip(CLASS_CHIP,TYPE_PROC);
ProcessorCoreType l_coreType = cpu_core_type();
bool l_haveOneCorrectProcessor = false;
TargetRangeFilter l_filter(
i_targetService.begin(),
i_targetService.end(),
&l_procChip);
for(;l_filter && (l_haveOneCorrectProcessor != true);++l_filter)
{
switch(l_filter->getAttr<ATTR_MODEL>())
{
case MODEL_VENICE:
if(l_coreType == CORE_POWER8_VENICE)
{
l_haveOneCorrectProcessor = true;
}
break;
case MODEL_MURANO:
if(l_coreType == CORE_POWER8_MURANO)
{
l_haveOneCorrectProcessor = true;
}
break;
case MODEL_NAPLES:
if(l_coreType == CORE_POWER8_NAPLES)
{
l_haveOneCorrectProcessor = true;
}
break;
case MODEL_NIMBUS:
if(l_coreType == CORE_POWER9_NIMBUS)
{
l_haveOneCorrectProcessor = true;
}
break;
case MODEL_CUMULUS:
if(l_coreType == CORE_POWER9_CUMULUS)
{
l_haveOneCorrectProcessor = true;
}
break;
case MODEL_AXONE:
if(l_coreType == CORE_POWER9_AXONE)
{
l_haveOneCorrectProcessor = true;
}
break;
default:
break;
};
}
TARG_ASSERT((l_haveOneCorrectProcessor == true), TARG_ERR_LOC "FATAL: No "
"targeted processors are of the correct type");
TARG_EXIT();
#undef TARG_FN
}
/*
* @brief Initialize any attributes that need to be set early on
*/
static void initializeAttributes(TargetService& i_targetService,
bool i_isMpipl,
bool i_istepMode,
ATTR_MASTER_MBOX_SCRATCH_type& i_masterScratch)
{
#define TARG_FN "initializeAttributes()...)"
TARG_ENTER();
Target* l_pTopLevel = NULL;
TargetHandleList l_chips;
i_targetService.getTopLevelTarget(l_pTopLevel);
if(l_pTopLevel)
{
//Set SKIP_WAKEUP to true until all cores are powered on (16.2)
//If this is not set to true, PM_RESET , which is called between
//now and istep 16.2 in various configurations and IPL flows will attempt
//to enable special wakeup on cores that are not yet powered
l_pTopLevel->setAttr<ATTR_SKIP_WAKEUP>(1);
Target* l_pMasterProcChip = NULL;
i_targetService.masterProcChipTargetHandle(l_pMasterProcChip);
if(l_pMasterProcChip)
{
// Master uses xscom by default, needs to be set before
// doing any other scom accesses
ScomSwitches l_switches =
l_pMasterProcChip->getAttr<ATTR_SCOM_SWITCHES>();
l_switches.useXscom = 1;
l_switches.useFsiScom = 0;
l_switches.useSbeScom = 0;
l_pMasterProcChip->setAttr<ATTR_SCOM_SWITCHES>(l_switches);
// Master can only use Host I2C so needs to be set before
// doing any I2C accesses
I2cSwitches l_i2c_switches =
l_pMasterProcChip->getAttr<ATTR_I2C_SWITCHES>();
l_i2c_switches.useHostI2C = 1;
l_i2c_switches.useFsiI2C = 0;
l_pMasterProcChip->setAttr<ATTR_I2C_SWITCHES>(l_i2c_switches);
l_pMasterProcChip->setAttr<ATTR_PROC_SBE_MASTER_CHIP>(1);
// Master has SBE started
l_pMasterProcChip->setAttr<ATTR_SBE_IS_STARTED>(1);
l_pTopLevel->setAttr<ATTR_MASTER_MBOX_SCRATCH>(i_masterScratch);
// Targeting data defaults to non istep, only turn "on" if bit
// is set so we don't tromp default setting
if (i_istepMode)
{
l_pTopLevel->setAttr<ATTR_ISTEP_MODE>(1);
}
else
{
l_pTopLevel->setAttr<ATTR_ISTEP_MODE>(0);
}
//Set the RISK_LEVEL ATTR based off of master Scratch regs if set
//otherwise use default level defined by system MRW
// Risk Level is a 4 bit value that is treated as an integer, but
// there is a legacy mode that we need to maintain support for
ATTR_RISK_LEVEL_type l_riskLevel =
l_pTopLevel->getAttr<ATTR_MRW_DEFAULT_RISK_LEVEL>();
INITSERVICE::SPLESS::MboxScratch8_t l_scratch8;
l_scratch8.data32 =
i_masterScratch[INITSERVICE::SPLESS::SCRATCH_8];
// Scratch5:bit2 is legacy risk level bit for backward compatibility
INITSERVICE::SPLESS::MboxScratch5_t l_scratch5;
l_scratch5.data32 =
i_masterScratch[INITSERVICE::SPLESS::SCRATCH_5];
if( l_scratch5.oldRiskLevel && l_scratch8.validHwpControlFlags)
{
l_riskLevel = 1;
}
// Scratch3 has the real risk level if the valid bit is on
else if (l_scratch8.validFwMode)
{
INITSERVICE::SPLESS::MboxScratch3_t l_scratch3;
l_scratch3.data32 =
i_masterScratch[INITSERVICE::SPLESS::SCRATCH_3];
l_riskLevel = l_scratch3.riskLevel;
}
else
{
// MRW used to setup RISK_LEVEL
l_pTopLevel->setAttr<ATTR_RISK_LEVEL_ORIGIN>
(RISK_LEVEL_ORIGIN_MRW);
}
TARG_INF( "Setting RISK_LEVEL=%d", l_riskLevel );
l_pTopLevel->setAttr<ATTR_RISK_LEVEL>(l_riskLevel);
//Set the SBE Console enablement based on our console enablement
ATTR_LPC_CONSOLE_CNFG_type l_console = LPC_CONSOLE_CNFG_ENABLE;
#ifndef CONFIG_CONSOLE
l_console = LPC_CONSOLE_CNFG_DISABLE;
#endif
l_pMasterProcChip->setAttr<ATTR_LPC_CONSOLE_CNFG>(l_console);
}
// Loop around all processors
TargetHandleList l_allProcChips;
getAllChips(l_allProcChips, TYPE_PROC, false);
for(auto l_chip : l_allProcChips)
{
// value for master set above
if( l_chip == l_pMasterProcChip )
{
continue;
}
//Turn the SBE Console enablement off for all slave chips
ATTR_LPC_CONSOLE_CNFG_type l_consoleOff = LPC_CONSOLE_CNFG_DISABLE;
l_chip->setAttr<ATTR_LPC_CONSOLE_CNFG>(l_consoleOff);
}
// Do some special memory-preserving work
if(i_isMpipl)
{
l_pTopLevel->setAttr<ATTR_IS_MPIPL_HB>(1);
//Clear out some attributes that could have stale data
l_pTopLevel->setAttr<ATTR_HB_RSV_MEM_NEXT_SECTION>(0);
l_pTopLevel->setAttr<ATTR_ATTN_CHK_ALL_PROCS>(1);
//Clear out PM MALF and FFDC enabled attributes
l_pTopLevel->setAttr<ATTR_PM_MALF_ALERT_ENABLE> (0x0);
l_pTopLevel->setAttr<ATTR_PM_RESET_FFDC_ENABLE> (0x0);
//Assemble list of functional procs and zero out virtual address values
//to ensure they get set again this IPL
TARGETING::PredicateCTM l_chipFilter(CLASS_CHIP, TYPE_PROC);
TARGETING::PredicateIsFunctional l_functional;
TARGETING::PredicatePostfixExpr l_functionalChips;
l_functionalChips.push(&l_chipFilter).push(&l_functional).And();
i_targetService.getAssociated( l_chips,
l_pTopLevel,
TargetService::CHILD_BY_AFFINITY,
TARGETING::TargetService::ALL,
&l_functionalChips);
for (auto & l_chip : l_chips)
{
l_chip->setAttr<ATTR_XSCOM_VIRTUAL_ADDR>(0);
l_chip->setAttr<ATTR_HOMER_VIRT_ADDR>(0);
l_chip->setAttr<ATTR_HB_INITIATED_PM_RESET>
(HB_INITIATED_PM_RESET_INACTIVE);
// clear the NVDIMM arming status so it gets redone when OCC is active
TargetHandleList l_nvdimmTargetList = getProcNVDIMMs(l_chip);
for (auto const l_nvdimm : l_nvdimmTargetList)
{
ATTR_NVDIMM_ARMED_type l_armed_state = {};
l_armed_state = l_nvdimm->getAttr<ATTR_NVDIMM_ARMED>();
// Only force rearming (error setting should persist)
l_armed_state.armed = 0;
l_armed_state.occ_active = 0;
l_nvdimm->setAttr<ATTR_NVDIMM_ARMED>(l_armed_state);
}
if (l_chip == l_pMasterProcChip)
{
// Need to set PROC_MASTER_TYPE to reflect the
// current acting master
l_chip->setAttr<ATTR_PROC_MASTER_TYPE>(PROC_MASTER_TYPE_ACTING_MASTER);
}
else
{
// If an different proc chip was previously the master
// (we assume this because the PROC_MASTER_TYPE
// attribute says so) we should change the attribute
// to indicate it could be the master again in the future
if (l_chip->getAttr<ATTR_PROC_MASTER_TYPE>()
== PROC_MASTER_TYPE_ACTING_MASTER)
{
l_chip->setAttr<ATTR_PROC_MASTER_TYPE>(PROC_MASTER_TYPE_MASTER_CANDIDATE);
}
//In certain IPL Scenarios this attribute may not get
// cleared properly, so clearing it for all proc chip
// targets that are not the master proc chip
l_chip->setAttr<ATTR_PROC_SBE_MASTER_CHIP>(0);
}
}
//Assemble list of tpms and zero out some values
//to ensure they get set again this IPL
TargetHandleList l_tpms;
TARGETING::PredicateCTM tpmFilter(CLASS_CHIP, TYPE_TPM);
i_targetService.getAssociated(
l_tpms,
l_pTopLevel,
TargetService::CHILD,
TARGETING::TargetService::ALL,
&tpmFilter);
for (auto & tpm : l_tpms)
{
tpm->setAttr<ATTR_HB_TPM_INIT_ATTEMPTED>(0);
tpm->setAttr<ATTR_HB_TPM_LOG_MGR_PTR>(0);
tpm->setAttr<ATTR_TPM_POISONED>(0);
}
//Assemble list of membuf and zero out some virtual address attributes
//to ensure they get set again this IPL
TargetHandleList l_membufs;
TARGETING::PredicateCTM membufFilter(CLASS_CHIP, TYPE_MEMBUF);
i_targetService.getAssociated(
l_membufs,
l_pTopLevel,
TargetService::CHILD,
TARGETING::TargetService::ALL,
&membufFilter);
for (auto & membuf : l_membufs)
{
membuf->setAttr<ATTR_IBSCOM_VIRTUAL_ADDR>(0);
}
TARGETING::PredicateCTM l_eqFilter(CLASS_UNIT, TYPE_EQ);
TARGETING::PredicateCTM l_exFilter(CLASS_UNIT, TYPE_EX);
TARGETING::PredicateCTM l_ecFilter(CLASS_UNIT, TYPE_CORE);
TARGETING::PredicatePostfixExpr l_wakeupTargFilter;
l_wakeupTargFilter.push(&l_eqFilter).push(&l_exFilter).Or().push(&l_ecFilter).Or();
TargetHandleList l_wakeupTargs;
i_targetService.getAssociated( l_wakeupTargs,
l_pTopLevel,
TargetService::CHILD_BY_AFFINITY,
TARGETING::TargetService::ALL,
&l_wakeupTargFilter);
for (auto & l_targ : l_wakeupTargs)
{
l_targ->setAttr<ATTR_SPCWKUP_COUNT>(0);
}
// HYPCOMM section is only present for master node
if ( TARGETING::UTIL::isCurrentMasterNode() )
{
// Setup physical TOC address
uint64_t l_hbdTocAddr = AttrRP::getHbDataTocAddr();
// Variables to store information about Hostboot/Hypervisor
// communication area
uint64_t l_hypComm_virt_addr = 0;
uint64_t l_hypComm_phys_addr = 0;
uint64_t l_hypComm_size = 0;
// Now map the TOC to find the total size of the data section
Util::hbrtTableOfContents_t * l_toc_ptr =
reinterpret_cast<Util::hbrtTableOfContents_t *>(
mm_block_map(reinterpret_cast<void*>(l_hbdTocAddr),
ALIGN_PAGE(sizeof(Util::hbrtTableOfContents_t))));
// read the TOC and look for ATTR data section
l_hypComm_virt_addr = Util::hb_find_rsvd_mem_label(
Util::HBRT_MEM_LABEL_HYPCOMM,
l_toc_ptr,
l_hypComm_size);
//This will tell us how far from the beginning of
//the toc_ptr the hypComm area starts
uint64_t l_hypComm_offset = l_hypComm_virt_addr -
reinterpret_cast<uint64_t>(l_toc_ptr);
//Use the offset found w/ virtual addresses to determine
//the physical address of the hostboot/hypervisor comm area
l_hypComm_phys_addr = l_hbdTocAddr + l_hypComm_offset;
//Clear the mapped memory for the TOC,
//it is not longer needed as we have phys ptr
assert (0 == mm_block_unmap(reinterpret_cast<void*>(l_toc_ptr)),
"Failed to unmap hbData TOC");
// The hb/hyp communcation area is at the end of the hostboot
// data reserved mem section.
hbHypCommArea_t * l_hbHypComm_ptr =
reinterpret_cast<hbHypCommArea_t *>(
mm_block_map(reinterpret_cast<void*>(l_hypComm_phys_addr),
ALIGN_PAGE(sizeof(l_hypComm_size))));
// Make sure the magic number and version are valid
if( l_hbHypComm_ptr->magicNum == HYPECOMM_MAGIC_NUM &&
l_hbHypComm_ptr->version >= STRUCT_VERSION_FIRST )
{
// if the hrmor in the comm area is non-zero then
// set the payload base attribute
if( l_hbHypComm_ptr->hrmorAddress)
{
const uint64_t THREAD_STATE_RUNNING = 0x8000000000000000ULL;
TARG_INF("Setting ATTR_PAYLOAD_BASE to new hrmor given by hypervisor: 0x%lx",
l_hbHypComm_ptr->hrmorAddress);
//Mask off THREAD_STATE_RUNNING bit and
//then divide remaining address by 1 MB
uint64_t l_payloadBase_MB = ( (~(THREAD_STATE_RUNNING)) &
l_hbHypComm_ptr->hrmorAddress) / MEGABYTE;
//ATTR_PAYLOAD_BASE's is MB
l_pTopLevel->setAttr<ATTR_PAYLOAD_BASE>(l_payloadBase_MB);
}
else
{
TARG_INF("Using default HRMOR as hypervisor did notify us of a change in it's HRMOR on previous boot");
}
}
else
{
TARG_INF("Warning!! hbHypCommArea_t's version is invalid so we cannot check if hrmor has been changed");
}
// Clear the mapped memory for the hbHypComm area
assert(0 == mm_block_unmap(
reinterpret_cast<void*>(l_hbHypComm_ptr)),
"Failed to unmap hbHypComm area");
} // end of master node only HRMOR setup
}
else
{
l_pTopLevel->setAttr<ATTR_IS_MPIPL_HB>(0);
// Compute any values that might change based on a remap of memory
adjustMemoryMap(i_targetService);
if(!INITSERVICE::spBaseServicesEnabled())
{
TARGETING::Target* l_sys = NULL;
TARGETING::targetService().getTopLevelTarget(l_sys);
getAllChips(l_chips, TYPE_PROC, false);
ATTR_PROC_EFF_FABRIC_GROUP_ID_type l_eff_id;
ATTR_FABRIC_PRESENT_GROUPS_type l_fabric_groups = 0;
for(auto l_chip : l_chips)
{
// Read the fabric group id
l_eff_id = l_chip->getAttr<ATTR_PROC_EFF_FABRIC_GROUP_ID>();
// Set the corresponding bit in fabric groups
l_fabric_groups |= (1 <<
((sizeof(ATTR_FABRIC_PRESENT_GROUPS_type)
* 8)
- l_eff_id - 1));
}
l_sys->setAttr<ATTR_FABRIC_PRESENT_GROUPS>(l_fabric_groups);
}
}
// Set Hostboot load address across all (intentional) processors so that
// FSP can determine the Hostboot load address when cores are
// winkled (since during winkle, the core scratch register holding the
// Hostboot load address is cleared).
TargetHandleList procs;
const auto loadAddressBytes = cpu_spr_value(CPU_SPR_HRMOR);
(void)getAllChips(procs, TYPE_PROC,false);
for(auto pProc : procs)
{
pProc->setAttr<TARGETING::ATTR_HB_HRMOR_BYTES>(
loadAddressBytes);
}
}
else // top level is NULL - never expected
{
TARG_INF("Top level target is NULL");
}
TARG_EXIT();
#undef TARG_FN
}
/**
* @brief Utility macro to swap attributes
* @param[in] _attr Attribute ID
* @param[in] _master Master proc target
* @param[in] _victim Victim proc target
* @param[in] _cache Cache of victime attributes
*/
#define SWAP_ATTRIBUTE( _attr, _master, _victim, _cache ) \
{ \
_attr##_type l_masterVal = _master->getAttr<_attr>(); \
_victim->setAttr<_attr>(l_masterVal); \
TARG_INF( "%.8X>" #_attr "=%.16llX", get_huid(_victim), l_masterVal ); \
_master->setAttr<_attr>(_cache[_attr]); \
TARG_INF( "%.8X>" #_attr "=%.16llX", get_huid(_master), _cache[_attr] ); \
}
// Compute any values that might change based on a remap of memory
static void adjustMemoryMap( TargetService& i_targetService )
{
// Grab the value of the BARs that SBE booted with
uint64_t l_curXscomBAR = g_BlToHbDataManager.getXscomBAR();
uint64_t l_curLpcBAR = g_BlToHbDataManager.getLpcBAR();
TARG_INF( "adjustMemoryMap> xscom=%llX, lpc=%llX",
l_curXscomBAR, l_curLpcBAR );
// Get the master proc
Target* l_pMasterProcChip = nullptr;
i_targetService.masterProcChipTargetHandle(l_pMasterProcChip);
assert(l_pMasterProcChip,"No Master Proc");
// Save off the base (group0-chip0) value for the BARs
Target* l_pTopLevel = nullptr;
i_targetService.getTopLevelTarget(l_pTopLevel);
ATTR_XSCOM_BASE_ADDRESS_type l_xscomBase =
l_pTopLevel->getAttr<ATTR_XSCOM_BASE_ADDRESS>();
ATTR_LPC_BUS_ADDR_type l_lpcBase =
l_pTopLevel->getAttr<ATTR_LPC_BUS_ADDR>();
// Loop through all the procs to recompute all the BARs
// also find the victim to swap with
Target* l_swapVictim = nullptr;
std::map<ATTRIBUTE_ID,uint64_t> l_swapAttrs;
TARGETING::TargetHandleList l_funcProcs;
getAllChips(l_funcProcs, TYPE_PROC, false );
for( auto & l_procChip : l_funcProcs )
{
TARG_INF( "Proc=%.8X", get_huid(l_procChip) );
// Set effective fabric ids back to default values
ATTR_FABRIC_GROUP_ID_type l_groupId =
l_procChip->getAttr<ATTR_FABRIC_GROUP_ID>();
l_procChip->setAttr<ATTR_PROC_EFF_FABRIC_GROUP_ID>(l_groupId);
ATTR_FABRIC_CHIP_ID_type l_chipId =
l_procChip->getAttr<ATTR_FABRIC_CHIP_ID>();
l_procChip->setAttr<ATTR_PROC_EFF_FABRIC_CHIP_ID>(l_chipId);
// Compute default xscom BAR
ATTR_XSCOM_BASE_ADDRESS_type l_xscomBAR =
computeMemoryMapOffset( l_xscomBase, l_groupId, l_chipId );
//If SBE Xscom addr has SMF bit on... propagate
if(l_curXscomBAR & IS_SMF_ADDR_BIT)
{
l_xscomBAR |= IS_SMF_ADDR_BIT;
}
TARG_INF( " XSCOM=%.16llX", l_xscomBAR );
l_procChip->setAttr<ATTR_XSCOM_BASE_ADDRESS>(l_xscomBAR);
// See if this chip's space now belongs to the master
if( l_xscomBAR == l_curXscomBAR )
{
l_swapVictim = l_procChip;
TARG_INF( "Master Proc %.8X is using XSCOM BAR from %.8X, BAR=%.16llX", get_huid(l_pMasterProcChip), get_huid(l_swapVictim), l_curXscomBAR );
l_swapAttrs[ATTR_PROC_EFF_FABRIC_GROUP_ID] = l_groupId;
l_swapAttrs[ATTR_PROC_EFF_FABRIC_CHIP_ID] = l_chipId;
l_swapAttrs[ATTR_XSCOM_BASE_ADDRESS] = l_xscomBAR;
}
// Compute default LPC BAR
ATTR_LPC_BUS_ADDR_type l_lpcBAR =
computeMemoryMapOffset( l_lpcBase, l_groupId, l_chipId );
TARG_INF( " LPC=%.16llX", l_lpcBAR );
l_procChip->setAttr<ATTR_LPC_BUS_ADDR>(l_lpcBAR);
if( l_swapVictim == l_procChip )
{
l_swapAttrs[ATTR_LPC_BUS_ADDR] = l_lpcBAR;
}
// Paranoid double-check that LPC matches XSCOM...
if( ((l_lpcBAR == l_curLpcBAR) && (l_swapVictim != l_procChip))
||
((l_lpcBAR != l_curLpcBAR) && (l_swapVictim == l_procChip)) )
{
TARG_ERR("BARs do not match : LPC=%.16llX, XSCOM=%.16llX",
l_curLpcBAR, l_curXscomBAR );
TARG_ASSERT(false,"Mismatch between LPC and XSCOM BARs");
}
//Setup Interrupt Related Bars
ATTR_PSI_BRIDGE_BASE_ADDR_type l_psiBridgeBAR =
computeMemoryMapOffset(MMIO_GROUP0_CHIP0_PSI_BRIDGE_BASE_ADDR,
l_groupId,
l_chipId);
TARG_INF( " PSI_BRIDGE_BAR =%.16llX", l_psiBridgeBAR );
l_procChip->setAttr<ATTR_PSI_BRIDGE_BASE_ADDR>(l_psiBridgeBAR);
if( l_swapVictim == l_procChip)
{
l_swapAttrs[ATTR_PSI_BRIDGE_BASE_ADDR] = l_psiBridgeBAR;
}
ATTR_XIVE_CONTROLLER_BAR_ADDR_type l_xiveCtrlBAR =
computeMemoryMapOffset(MMIO_GROUP0_CHIP0_XIVE_CONTROLLER_BASE_ADDR,
l_groupId,
l_chipId);
TARG_INF( " XIVE_CONTROLLER_BAR =%.16llX", l_xiveCtrlBAR );
l_procChip->setAttr<ATTR_XIVE_CONTROLLER_BAR_ADDR>(l_xiveCtrlBAR);
if( l_swapVictim == l_procChip)
{
l_swapAttrs[ATTR_XIVE_CONTROLLER_BAR_ADDR] = l_xiveCtrlBAR;
}
ATTR_XIVE_THREAD_MGMT1_BAR_ADDR_type l_xiveThreadMgmtBAR =
computeMemoryMapOffset(MMIO_GROUP0_CHIP0_XIVE_THREAD_MGMT1_BASE_ADDR,
l_groupId,
l_chipId);
TARG_INF( " XIVE_THREAD_MGMT1_BAR =%.16llX", l_xiveThreadMgmtBAR );
l_procChip->setAttr<ATTR_XIVE_THREAD_MGMT1_BAR_ADDR>(l_xiveThreadMgmtBAR);
if( l_swapVictim == l_procChip)
{
l_swapAttrs[ATTR_XIVE_THREAD_MGMT1_BAR_ADDR] = l_xiveThreadMgmtBAR;
}
ATTR_PSI_HB_ESB_ADDR_type l_psiHbEsbBAR =
computeMemoryMapOffset(MMIO_GROUP0_CHIP0_PSI_HB_ESB_BASE_ADDR,
l_groupId,
l_chipId);
TARG_INF( " PSI_HB_ESB_BAR =%.16llX", l_psiHbEsbBAR );
l_procChip->setAttr<ATTR_PSI_HB_ESB_ADDR>(l_psiHbEsbBAR);
if( l_swapVictim == l_procChip)
{
l_swapAttrs[ATTR_PSI_HB_ESB_ADDR] = l_psiHbEsbBAR;
}
ATTR_INTP_BASE_ADDR_type l_intpBAR =
computeMemoryMapOffset(MMIO_GROUP0_CHIP0_INTP_BASE_ADDR,
l_groupId,
l_chipId);
TARG_INF( " INTP_BAR =%.16llX", l_intpBAR );
l_procChip->setAttr<ATTR_INTP_BASE_ADDR>(l_intpBAR);
if( l_swapVictim == l_procChip)
{
l_swapAttrs[ATTR_INTP_BASE_ADDR] = l_intpBAR;
}
//finished setting up interrupt bars
// Set the rest of the BARs...
}
// We should have found a match, but if a processor was swapped
// between different systems we could end up with a non-match
if( l_swapVictim == nullptr )
{
TARG_INF( "No swap victim was found, forcing master proc to use calculated proc0 values" );
// figure out what fabric id we actually booted with
uint8_t l_bootGroup = 0;
uint8_t l_bootChip = 0;
getFabricIdFromAddr( l_curXscomBAR, l_bootGroup, l_bootChip );
CONSOLE::displayf( NULL, "Module swap detected - handling memory remap from g%d:c%d\n", l_bootGroup, l_bootChip );
// now adjust the attributes that our early code is going to consume
// to match the fabric id we're currently using
ATTR_XSCOM_BASE_ADDRESS_type l_xscomBAR =
computeMemoryMapOffset( l_xscomBase, l_bootGroup, l_bootChip );
l_pMasterProcChip->setAttr<ATTR_XSCOM_BASE_ADDRESS>(l_xscomBAR);
ATTR_LPC_BUS_ADDR_type l_lpcBAR =
computeMemoryMapOffset( l_lpcBase, l_bootGroup, l_bootChip );
l_pMasterProcChip->setAttr<ATTR_LPC_BUS_ADDR>(l_lpcBAR);
ATTR_PSI_BRIDGE_BASE_ADDR_type l_psiBridgeBAR =
computeMemoryMapOffset(MMIO_GROUP0_CHIP0_PSI_BRIDGE_BASE_ADDR,
l_bootGroup,
l_bootChip);
l_pMasterProcChip->setAttr<ATTR_PSI_BRIDGE_BASE_ADDR>(l_psiBridgeBAR);
ATTR_XIVE_CONTROLLER_BAR_ADDR_type l_xiveCtrlBAR =