windows-nt/Source/XPSP1/NT/base/hals/halia64/ia64/osmca.c
2020-09-26 16:20:57 +08:00

1995 lines
53 KiB
C

//** Copyright (C) 1996-2000 Intel Corporation. All rights reserved.
//**
//** The information and source code contained herein is the exclusive
//** property of Intel Corporation and may not be disclosed, examined
//** or reproduced in whole or in part without explicit written authorization
//** from the company.
//**
//###########################################################################
//-----------------------------------------------------------------------------
// Version control information follows.
//
//
// 10 Jun 1999 Bugcheck Bernard Lint
// M. Jayakumar (Muthurajan.Jayakumar@intel.com)
// Thierry Fevrier
///////////////////////////////////////////////////////////////////////////////
//
// Module Name: OSMCA.C - Merced OS Machine Check Handler
//
// Description:
// This module has OS Machine Check Handler Reference Code.
//
// Contents: HalpOsMcaInit()
// HalpCmcHandler()
// HalpMcaHandler()
// HalpMcRzHandlr()
// HalpMcWkupHandlr()
// HalpProcMcaHndlr()
// HalpPlatMcaHndlr()
//
//
// Target Platform: Merced
//
// Reuse: None
//
////////////////////////////////////////////////////////////////////////////M//
#include "halp.h"
#include "nthal.h"
#include "arc.h"
#include "i64fw.h"
#include "check.h"
#include "iosapic.h"
#include "inbv.h"
#include "osmca.h"
// pmdata.c: CPE definitions.
extern ULONG HalpMaxCPEImplemented;
extern ULONG HalpCPEIntIn[];
// i64fw.c: HAL Private Data structure for SAL/PAL
extern HALP_SAL_PAL_DATA HalpSalPalData;
// i64fwasm.s: low-level protection data structures
extern KSPIN_LOCK HalpMcaSpinLock;
extern KSPIN_LOCK HalpCmcSpinLock;
extern KSPIN_LOCK HalpCpeSpinLock;
//
// IA64 MCE Info structures to keep track of MCE features
// available on installed hardware.
//
HALP_MCA_INFO HalpMcaInfo;
HALP_CMC_INFO HalpCmcInfo;
HALP_CPE_INFO HalpCpeInfo;
KERNEL_MCE_DELIVERY HalpMceKernelDelivery;
volatile ULONG HalpOsMcaInProgress = 0;
//
// SAL_MC_SET_PARAMS.time_out
//
ULONGLONG HalpMcRendezTimeOut = HALP_DEFAULT_MC_RENDEZ_TIMEOUT;
//
// HalpProcessorMcaRecords:
//
// Number of MCA records pre-allocated per processor.
//
ULONGLONG HalpProcessorMcaRecords = HALP_DEFAULT_PROCESSOR_MCA_RECORDS;
//
// HalpProcessorInitRecords:
//
// Number of INIT records pre-allocated per processor.
//
ULONGLONG HalpProcessorInitRecords = HALP_DEFAULT_PROCESSOR_INIT_RECORDS;
//
// HalpMceLogsMaxCount:
//
// Maximum number of saved logs.
//
ULONG HalpMceLogsMaxCount = HALP_MCELOGS_MAXCOUNT;
//
// HAL Private Error Device GUIDs:
// [useful for kdexts]
//
ERROR_DEVICE_GUID HalpErrorProcessorGuid = ERROR_PROCESSOR_GUID;
ERROR_DEVICE_GUID HalpErrorMemoryGuid = ERROR_MEMORY_GUID;
ERROR_DEVICE_GUID HalpErrorPciBusGuid = ERROR_PCI_BUS_GUID;
ERROR_DEVICE_GUID HalpErrorPciComponentGuid = ERROR_PCI_COMPONENT_GUID;
ERROR_DEVICE_GUID HalpErrorSystemEventLogGuid = ERROR_SYSTEM_EVENT_LOG_GUID;
ERROR_DEVICE_GUID HalpErrorSmbiosGuid = ERROR_SMBIOS_GUID;
ERROR_DEVICE_GUID HalpErrorPlatformSpecificGuid = ERROR_PLATFORM_SPECIFIC_GUID;
ERROR_DEVICE_GUID HalpErrorPlatformBusGuid = ERROR_PLATFORM_BUS_GUID;
ERROR_DEVICE_GUID HalpErrorPlatformHostControllerGuid = ERROR_PLATFORM_HOST_CONTROLLER_GUID;
//
// HAL Private Error Definitions:
// [useful for kdexts]
// Actually in this case, the typed pointers allow also the inclusion of the symbols definitions
// without the data structures sizes.
//
PERROR_MODINFO HalpPErrorModInfo;
PERROR_PROCESSOR_CPUID_INFO HalpPErrorProcessorCpuIdInfo;
PERROR_PROCESSOR HalpPErrorProcessor;
PERROR_PROCESSOR_STATIC_INFO HalpPErrorProcessorStaticInfo;
PERROR_MEMORY HalpPErrorMemory;
PERROR_PCI_BUS HalpPErrorPciBus;
PERROR_PCI_COMPONENT HalpPErrorPciComponent;
PERROR_SYSTEM_EVENT_LOG HalpPErrorSystemEventLog;
PERROR_SMBIOS HalpPErrorSmbios;
PERROR_PLATFORM_SPECIFIC HalpPErrorPlatformSpecific;
PERROR_PLATFORM_BUS HalpPErrorPlatformBus;
PERROR_PLATFORM_HOST_CONTROLLER HalpPErrorPlatformHostController;
//
// MCA/CMC/CPE state catchers
//
ERROR_SEVERITY
HalpMcaProcessLog(
PMCA_EXCEPTION McaLog
);
BOOLEAN
HalpPreAllocateMceTypeRecords(
ULONG EventType,
ULONG Number
);
VOID
HalpMcaBugCheck(
ULONG McaBugCheckType,
PMCA_EXCEPTION McaLog,
ULONGLONG McaAllocatedLogSize,
ULONGLONG Arg4
);
#ifdef ALLOC_PRAGMA
#pragma alloc_text(INIT, HalpInitializeOSMCA)
#pragma alloc_text(INIT, HalpAllocateMceStacks)
#pragma alloc_text(INIT, HalpPreAllocateMceRecords)
#pragma alloc_text(INIT, HalpPreAllocateMceTypeRecords)
#pragma alloc_text(PAGELK, HalpMcaHandler)
#pragma alloc_text(PAGELK, HalpMcaProcessLog)
#pragma alloc_text(PAGELK, HalpMcaBugCheck)
#pragma alloc_text(PAGELK, HalpGetErrLog)
#pragma alloc_text(PAGELK, HalpClrErrLog)
#pragma alloc_text(PAGE, HalpGetMceInformation)
#endif // ALLOC_PRAGMA
BOOLEAN
HalpSaveEventLog(
PSINGLE_LIST_ENTRY HeadList,
PERROR_RECORD_HEADER RecordHeader,
ULONG Tag,
POOL_TYPE PoolType,
PKSPIN_LOCK SpinLock
)
{
PSINGLE_LIST_ENTRY entry, previousEntry;
SIZE_T logSize;
PERROR_RECORD_HEADER savedLog;
KIRQL oldIrql;
//
// Allocate and Initialize the new entry
//
logSize = RecordHeader->Length;
if ( !logSize ) {
HalDebugPrint(( HAL_ERROR, "HAL!HalpSaveEventLog: record length is zeroed.\n" ));
return FALSE;
}
entry = (PSINGLE_LIST_ENTRY)ExAllocatePoolWithTag( PoolType, sizeof(*entry) + logSize, Tag );
if ( entry == NULL ) {
HalDebugPrint(( HAL_ERROR, "HAL!HalpSaveEventLog: Event log allocation failed.\n" ));
return FALSE;
}
entry->Next = NULL;
savedLog = (PERROR_RECORD_HEADER)((ULONG_PTR)entry + sizeof(*entry));
RtlCopyMemory( savedLog, RecordHeader, logSize );
//
// Insert the new entry with protection.
//
KeRaiseIrql( HIGH_LEVEL, &oldIrql );
KiAcquireSpinLock( SpinLock );
previousEntry = HeadList;
while( previousEntry->Next != NULL ) {
previousEntry = previousEntry->Next;
}
previousEntry->Next = entry;
KiReleaseSpinLock( SpinLock );
KeLowerIrql( oldIrql );
return TRUE;
} // HalpSaveEventLog()
#define HalpSaveCorrectedMcaLog( _McaLog ) \
HalpSaveEventLog( &HalpMcaInfo.CorrectedLogs, (PERROR_RECORD_HEADER)(_McaLog), 'CacM', NonPagedPool, &HalpMcaSpinLock )
NTSTATUS
HalpCheckForMcaLogs(
VOID
)
/*++
Routine Description:
This routine checks the FW early during boot if a MCA event log is present.
The log is considered as "previous".
This routine is called at phase 1 on BSP and APs, from HalpPreAllocateMceRecords().
it is executed on the standard kernel stacks.
Arguments:
None
Return Value:
STATUS_NO_MEMORY if mca log allocation failed.
STATUS_SUCCESS otherwise, regardless of FW interfaces failures.
--*/
{
NTSTATUS status;
PERROR_RECORD_HEADER log;
log = ExAllocatePoolWithTag( NonPagedPool, HalpMcaInfo.Stats.MaxLogSize, 'PacM' );
if ( !log ) {
return( STATUS_NO_MEMORY );
}
status = HalpGetFwMceLog( MCA_EVENT, log, &HalpMcaInfo.Stats, HALP_FWMCE_DONOT_CLEAR_LOG );
if ( status != STATUS_NOT_FOUND ) {
//
// Successful log collection or invalid record or unsuccessful FW Interface calls
// are considered as a trigger for the MCA log consumers to collect them from the FW.
//
InterlockedIncrement( &HalpMcaInfo.Stats.McaPreviousCount );
}
ExFreePoolWithTag( log, 'PacM' );
return( STATUS_SUCCESS );
} // HalpCheckForMcaLogs()
BOOLEAN
HalpPreAllocateMceTypeRecords(
ULONG EventType,
ULONG Number
)
{
SAL_PAL_RETURN_VALUES rv = {0};
ULONGLONG defaultEventRecords;
PVOID log;
SIZE_T logSize;
PHYSICAL_ADDRESS physicalAddr;
if ( (EventType != MCA_EVENT) && (EventType != INIT_EVENT) ) {
ASSERTMSG( "HAL!HalpPreAllocateMceTypeRecords: unknown event type!\n", FALSE );
return FALSE;
}
//
// On BSP only, call SAL to get maximum size of EventType record
//
if ( Number == 0 ) {
rv = HalpGetStateInfoSize( EventType );
if ( !SAL_SUCCESSFUL(rv) ) {
HalDebugPrint(( HAL_ERROR, "HAL!HalpPreAllocateMceTypeRecords: SAL_GET_STATE_INFO_SIZE failed...\n" ));
return FALSE;
}
logSize = rv.ReturnValues[1];
}
if ( EventType == MCA_EVENT ) {
if ( Number == 0 ) {
// Update HalpMcaInfo, without protection. This is not required.
HalpMcaInfo.Stats.MaxLogSize = (ULONG)logSize;
}
else {
logSize = (SIZE_T)HalpMcaInfo.Stats.MaxLogSize;
}
defaultEventRecords = HalpProcessorMcaRecords;
}
else {
ASSERTMSG( "HAL!HalpPreAllocateMceTypeRecords: invalid event type!\n", EventType == INIT_EVENT );
if ( Number == 0 ) {
// Update HalpInitInfo, without protection. This is not required.
HalpInitInfo.MaxLogSize = (ULONG)logSize;
}
else {
logSize = (SIZE_T)HalpInitInfo.MaxLogSize;
}
defaultEventRecords = HalpProcessorInitRecords;
}
// Determine size of allocation
logSize = ROUND_TO_PAGES( (logSize * defaultEventRecords) );
//
// Allocate Event Records buffer
//
physicalAddr.QuadPart = 0xffffffffffffffffI64;
log = MmAllocateContiguousMemory( logSize, physicalAddr );
if ( log == NULL ) {
HalDebugPrint(( HAL_ERROR, "HAL!HalpPreAllocateMceTypeRecords: SAL %s Event Records allocation failed (0x%Ix)...\n",
( EventType == MCA_EVENT ) ? "MCA" : "INIT",
logSize ));
return FALSE;
}
//
// Update KPCR entry.
//
{
volatile KPCR * const pcr = KeGetPcr();
PSAL_EVENT_RESOURCES eventResources;
if ( EventType == MCA_EVENT ) {
eventResources = pcr->OsMcaResourcePtr;
}
eventResources->EventPool = log;
eventResources->EventPoolSize = (ULONG) logSize;
}
return TRUE;
} // HalpPreAllocateMceTypeRecords()
BOOLEAN
HalpPreAllocateMceRecords(
IN ULONG Number
)
{
NTSTATUS status;
//
// Pre-Allocate MCA records
//
if ( !HalpPreAllocateMceTypeRecords( MCA_EVENT , Number ) ) {
return FALSE;
}
//
// Check for MCA logs.
// These might be logs related to previous boot sessions.
//
status = HalpCheckForMcaLogs();
if ( !NT_SUCCESS( status ) ) {
return FALSE;
}
return TRUE;
} // HalpPreAllocateMceRecords()
BOOLEAN
HalpAllocateMceStacks(
IN ULONG Number
)
{
PHYSICAL_ADDRESS physicalAddr;
PVOID mem;
PVOID mcaStateDump, mcaBackStore, mcaStack;
ULONGLONG mcaStateDumpPhysical;
ULONGLONG mcaBackStoreLimit, mcaStackLimit;
ULONG length;
//
// Allocate MCA/INIT stacks
//
length = HALP_MCA_STATEDUMP_SIZE + HALP_MCA_BACKSTORE_SIZE + HALP_MCA_STACK_SIZE;
physicalAddr.QuadPart = 0xffffffffffffffffI64;
mem = MmAllocateContiguousMemory( length, physicalAddr );
if ( mem == NULL ) {
HalDebugPrint(( HAL_ERROR, "HAL!HalpAllocateMceStacks: MCA State Dump allocation failed (0x%Ix)...\n",
length ));
return FALSE;
}
//
// The layout in memory by increasing addresses is:
//
// Bottom of stack
// .
// .
// .
// Initial Stack
// State Dump Area
// .
// .
// Initial BSP
// .
// .
// .
// BSP Limit
//
mcaStack = mem;
mcaStackLimit = (ULONGLONG)mem + HALP_MCA_STACK_SIZE;
mem = (PCHAR) mem + HALP_MCA_STACK_SIZE;
mcaStateDump = mem;
mcaStateDumpPhysical = MmGetPhysicalAddress(mem).QuadPart;
mem = (PCHAR) mem + HALP_MCA_STATEDUMP_SIZE;
mcaBackStore = mem;
mcaBackStoreLimit = (ULONGLONG)mem + (ULONGLONG)(ULONG)HALP_MCA_BACKSTORE_SIZE;
//
// Update PCR MCA, INIT stacks
//
{
volatile KPCR * const pcr = KeGetPcr();
PSAL_EVENT_RESOURCES eventResources;
eventResources = pcr->OsMcaResourcePtr;
eventResources->StateDump = mcaStateDump;
eventResources->StateDumpPhysical = mcaStateDumpPhysical;
eventResources->BackStore = mcaBackStore;
eventResources->BackStoreLimit = mcaBackStoreLimit;
eventResources->Stack = (PCHAR) mcaStackLimit;
eventResources->StackLimit = (ULONGLONG) mcaStack;
}
return TRUE;
} // HalpPreAllocateMceRecords()
//++
// Name: HalpInitializeOSMCA()
//
// Routine Description:
//
// This routine registers MCA init's
//
// Arguments On Entry:
// arg0 = Function ID
//
// Success/Failure (0/!0)
//--
BOOLEAN
HalpInitializeOSMCA(
IN ULONG Number
)
{
SAL_PAL_RETURN_VALUES rv = {0};
ULONGLONG gp_reg;
//
// Register SAL_MC_RendezVous parameters with SAL
//
rv = HalpSalSetParams(0, RendzType, IntrVecType, MC_RZ_VECTOR, HalpMcRendezTimeOut);
if ( !SAL_SUCCESSFUL(rv) ) {
HalDebugPrint(( HAL_ERROR, "HAL!HalpInitializeOSMCA: SAL_MC_SET_PARAMS.rendezvous vector failed...\n" ));
return FALSE;
}
//
// Register WakeUp parameters with SAL
//
rv = HalpSalSetParams(0, WakeUpType, IntrVecType, MC_WKUP_VECTOR,0);
if ( !SAL_SUCCESSFUL(rv) ) {
HalDebugPrint(( HAL_ERROR, "HAL!HalpInitializeOSMCA: SAL_MC_SET_PARAMS.wakeup vector failed...\n" ));
return FALSE;
}
//
// Allocate MCA, INIT stacks
//
if ( !HalpAllocateMceStacks( Number ) ) {
return FALSE;
}
//
// Pre-Allocate desired number of MCA,INIT records
//
HalpMcaInfo.KernelToken = (PVOID)(ULONG_PTR)HALP_KERNEL_TOKEN;
if ( !HalpPreAllocateMceRecords( Number ) ) {
return FALSE;
}
//
// Initialize HAL private CMC, CPE structures.
//
rv = HalpGetStateInfoSize( CMC_EVENT );
if ( !SAL_SUCCESSFUL( rv ) ) {
HalDebugPrint(( HAL_ERROR, "HAL!HalpInitializeOSMCA: SAL_GET_STATE_INFO_SIZE.CMC failed...\n" ));
return FALSE;
}
HalpCmcInfo.Stats.MaxLogSize = (ULONG)rv.ReturnValues[1];
HalpCmcInfo.KernelToken = (PVOID)(ULONG_PTR)HALP_KERNEL_TOKEN;
HalpCmcInfo.KernelLogs.MaxCount = HalpMceLogsMaxCount;
HalpCmcInfo.DriverLogs.MaxCount = HalpMceLogsMaxCount;
HalpCmcInfo.Stats.PollingInterval = HAL_CMC_INTERRUPTS_BASED;
rv = HalpGetStateInfoSize( CPE_EVENT );
if ( !SAL_SUCCESSFUL( rv ) ) {
HalDebugPrint(( HAL_ERROR, "HAL!HalpInitializeOSMCA: SAL_GET_STATE_INFO_SIZE.CPE failed...\n" ));
return FALSE;
}
HalpCpeInfo.Stats.MaxLogSize = (ULONG)rv.ReturnValues[1];
HalpCpeInfo.KernelToken = (PVOID)(ULONG_PTR)HALP_KERNEL_TOKEN;
HalpCpeInfo.KernelLogs.MaxCount = HalpMceLogsMaxCount;
HalpCpeInfo.DriverLogs.MaxCount = HalpMceLogsMaxCount;
//
// Register OsMcaDispatch (OS_MCA) physical address with SAL
//
gp_reg = GetGp();
rv = HalpSalSetVectors(0, MchkEvent, MmGetPhysicalAddress((fptr)(((PLabel*)HalpOsMcaDispatch1)->fPtr)), gp_reg,0);
if ( !SAL_SUCCESSFUL(rv) ) {
HalDebugPrint(( HAL_ERROR, "HAL!HalpInitializeOSMCA: SAL_SET_VECTOR.MCA vector failed...\n" ));
return FALSE;
}
//
// Register OsInitDispatch physical address with SAL
//
rv = HalpSalSetVectors(0, InitEvent, MmGetPhysicalAddress((fptr)(((PLabel*)HalpOsInitDispatch)->fPtr)), gp_reg,0);
if ( !SAL_SUCCESSFUL(rv) ) {
HalDebugPrint(( HAL_ERROR, "HAL!HalpInitializeOSMCA: SAL_SET_VECTOR.INIT vector failed...\n" ));
return FALSE;
}
return TRUE;
} // HalpInitializeOSMCA()
//EndProc//////////////////////////////////////////////////////////////////////
VOID
HalpMcaBugCheck(
ULONG McaBugCheckType,
PMCA_EXCEPTION McaLog,
ULONGLONG McaAllocatedLogSize,
ULONGLONG SalStatus
)
//++
// Name: HalpMcaBugCheck()
//
// Routine Description:
//
// This function is called to bugcheck the system in a case of a fatal MCA
// or fatal FW interface errors. The OS must guarantee as much as possible
// error containment in this path.
// With the current implementation, this function should be only called from
// the OS_MCA path. For other MCA specific wrappers of KeBugCheckEx, one should
// HalpMcaKeBugCheckEx().
//
// Arguments On Entry:
// ULONG McaBugCheckType
// PMCA_EXCEPTION McaLog
// ULONGLONG McaAllocatedLogSize
// ULONGLONG SalStatus
//
// Return:
// None.
//
// Implementation notes:
// This code CANNOT [as default rules - at least entry and through fatal MCAs handling]
// - make any system call
// - attempt to acquire any spinlock used by any code outside the MCA handler
// - change the interrupt state.
// Passing data to non-MCA code must be done using manual semaphore instructions.
// This code should minimize the path and the global or memory allocated data accesses.
// This code should only access MCA-namespace structures.
// This code is called under the MP protection of HalpMcaSpinLock and with the flag
// HalpOsMcaInProgress set.
//
//--
{
if ( HalpOsMcaInProgress ) {
//
// Enable InbvDisplayString calls to make it through to bootvid driver.
//
if ( InbvIsBootDriverInstalled() ) {
InbvAcquireDisplayOwnership();
InbvResetDisplay();
InbvSolidColorFill(0,0,639,479,4); // make the screen blue
InbvSetTextColor(15);
InbvInstallDisplayStringFilter((INBV_DISPLAY_STRING_FILTER)NULL);
InbvEnableDisplayString(TRUE); // enable display string
InbvSetScrollRegion(0,0,639,479); // set to use entire screen
}
HalDisplayString (MSG_MCA_HARDWARE_ERROR);
HalDisplayString (MSG_HARDWARE_ERROR2);
//
// Thierry 09/2000:
//
// - if desired, process the MCA log HERE...
//
// and use HalDisplayString() to dump info for the field or hardware vendor.
// The processing could be based on processor or platform independent record definitions.
//
HalDisplayString( MSG_HALT );
if ( HalpMcaInfo.NoBugCheck == 0 ) {
KeBugCheckEx( MACHINE_CHECK_EXCEPTION, (ULONG_PTR)McaBugCheckType,
(ULONG_PTR)McaLog,
(ULONG_PTR)McaAllocatedLogSize,
(ULONG_PTR)SalStatus );
}
}
if ( ((*KdDebuggerNotPresent) == FALSE) && ((*KdDebuggerEnabled) != FALSE) ) {
KeEnterKernelDebugger();
}
while( TRUE ) {
//
; // Simply sit here so the MCA HARDWARE ERROR screen does not get corrupted...
//
}
// noreturn
} // HalpMcaBugCheck()
ERROR_SEVERITY
HalpMcaProcessLog(
PMCA_EXCEPTION McaLog
)
//++
// Name: HalpMcaProcessLog()
//
// Routine Description:
//
// This function is called to process the MCA event log in the OS_MCA path.
//
// Arguments On Entry:
// PMCA_EXCEPTION McaLog - Pointer to the MCA event log.
//
// Return:
// ERROR_SEVERITY
//
// Implementation notes:
// This code CANNOT [as default rules]
// - make any system call
// - attempt to acquire any spinlock used by any code outside the MCA handler
// - change the interrupt state.
// Passing data to non-MCA code must be done using manual semaphore instructions.
// This code should minimize the path and the global or memory allocated data accesses.
// This code should only access MCA-namespace structures.
// This code is called under the MP protection of HalpMcaSpinLock and with the flag
// HalpOsMcaInProgress set.
//
//--
{
ERROR_SEVERITY mcaSeverity;
mcaSeverity = McaLog->ErrorSeverity;
switch( mcaSeverity ) {
case ErrorFatal:
break;
case ErrorRecoverable:
//
// Thierry - FIXFIX 08/2000:
//
///////////////////////////////////////////////////////////////
//
// Call to kernel supported recovery will be here....
//
///////////////////////////////////////////////////////////////
//
// However, for now we do not recover so flag it as ErrorFatal.
mcaSeverity = ErrorFatal;
break;
case ErrorCorrected:
default:
//
// These ERRROR_SEVERITY values have no HAL MCA specific handling.
// As specified by the SAL Specs July 2000, we should not get these values in this path.
//
break;
}
//
// If OEM driver has registered an exception callback for MCA event,
// call it here and save returned error severity value.
//
if ( HalpMcaInfo.DriverInfo.ExceptionCallback ) {
mcaSeverity = HalpMcaInfo.DriverInfo.ExceptionCallback(
HalpMcaInfo.DriverInfo.DeviceContext,
McaLog );
}
//
// Save corrected log for future kernel notification.
//
if ( (HalpMcaInfo.KernelDelivery) && (mcaSeverity == ErrorCorrected) ) {
InterlockedIncrement( &HalpMcaInfo.Stats.McaCorrectedCount );
#if 0
//
// Thierry - 09/16/2000: ToBeDone.
// Saving the corrected MCA log records requires careful rendez-vous configuration
// handling, possible OS_MCA monarch selection, MCA logs (pre-)allocations and
// special locking in case a consumer accesses the logs queue on another processor.
//
// The kernel-WMI and/or OEM MCA driver notification is done in HalpMcaHandler().
//
if ( !HalpSaveCorrectedMcaLog( McaLog ) ) {
InterlockedIncrement( &HalpMcaInfo.CorrectedLogsLost );
}
#endif // 0
//
// The kernel-WMI and/or OEM MCA driver notification for corrected MCA event
// is done in HalpMcaHandler().
//
}
//
// Thierry 10/17/2000 BUGBUG
//
// The FW does not save the MCA log in NVRAM and we have no official date from Intel
// when the SAL will be doing it.
// So for now, return as ErrorFatal and let dump the log through the debugger.
//
// Before Sal Rev <ToBeDetermined>, the error logs were completely erroneous...
//
if ( HalpSalPalData.SalRevision.Revision < HALP_SAL_REVISION_MAX ) {
return( ErrorFatal );
}
else {
return( mcaSeverity );
}
} // HalpMcaProcessLog()
SAL_PAL_RETURN_VALUES
HalpMcaHandler(
ULONG64 RendezvousState,
PPAL_MINI_SAVE_AREA Pmsa
)
//++
// Name: HalpMcaHandler()
//
// Routine Description:
//
// This is the OsMca handler for firmware uncorrected errors
// It is our option to run this in physical or virtual mode.
//
// Arguments On Entry:
// None.
//
// Conditions On Entry: 09/2000 implementation.
// - PSR state: at least,
// PSR.dt = 1, PSR.it = 1, PSR.rt = 1 - virtual mode.
// PSR.ic = 1, PSR.i = 0 - Interruption resources collection enabled,
// Interrupts off.
// PSR.mc = 1 - MCA masked for this processor.
// - SalToOsHndOff initialized.
// - s0 = MinStatePtr.
// - s1 = IA64 PAL Processor State Parameter.
// - s2 = PALE_CHECK return address.
// - Processor registers state saved in myStateDump[] by osmcaProcStateDump().
// - myStackFrame[0] = ar.rsc
// - myStackFrame[1] = ar.pfs
// - myStackFrame[2] = ar.ifs
// - myStackFrame[3] = ar.bspstore
// - myStackFrame[4] = ar.rnat
// - myStackFrame[5] = ar.bsp - ar.bspstore
// - ar.bspstore = myBspStore
// - sp = &mySp[sizeof(mySp[])]
//
// Return:
// rtn0=Success/Failure (0/!0)
// rtn1=Alternate MinState Pointer if any else NULL
//
// Implementation notes:
// This code CANNOT [as default rules - at least entry and through fatal MCAs handling]
// - make any system call
// - attempt to acquire any spinlock used by any code outside the MCA handler
// - change the interrupt state.
// Passing data to non-MCA code must be done using manual semaphore instructions.
// This code should minimize the path and the global or memory allocated data accesses.
// This code should only access MCA-namespace structures and should not access globals
// until it is safe.
//
//--
{
SAL_PAL_RETURN_VALUES rv;
LONGLONG salStatus;
BOOLEAN mcWakeUp;
PMCA_EXCEPTION mcaLog;
ULONGLONG mcaAllocatedLogSize;
PSAL_EVENT_RESOURCES mcaResources;
KIRQL oldIrql;
volatile KPCR * const pcr = KeGetPcr();
//
// Acquire MCA spinlock protecting OS_MCA resources.
//
// Thierry 10/06/2000: FIXFIX.
// we will move this MP synchronization in HalpOsMcaDispatch after current discussions
// with Intel about MP MCA handling are completed.
// Expecting responses from Intel about these.
//
KeRaiseIrql(HIGH_LEVEL, &oldIrql);
HalpAcquireMcaSpinLock( &HalpMcaSpinLock );
HalpOsMcaInProgress++;
//
// Save OsToSal minimum state
//
mcaResources = pcr->OsMcaResourcePtr;
mcaResources->OsToSalHandOff.SalReturnAddress = mcaResources->SalToOsHandOff.SalReturnAddress;
mcaResources->OsToSalHandOff.SalGlobalPointer = mcaResources->SalToOsHandOff.SalGlobalPointer;
//
// update local variables with pre-initialized MCA log data.
//
mcaLog = (PMCA_EXCEPTION)(mcaResources->EventPool);
mcaAllocatedLogSize = mcaResources->EventPoolSize;
if ( !mcaLog || !mcaAllocatedLogSize ) {
//
// The following code should never happen or the implementation of the HAL MCA logs
// pre-allocation failed miserably. This would be a development error.
//
HalpMcaBugCheck( (ULONG_PTR)HAL_BUGCHECK_MCA_ASSERT, mcaLog,
mcaAllocatedLogSize,
(ULONGLONG)0 );
}
//
// Get the MCA logs
//
salStatus = (LONGLONG)0;
while( salStatus >= 0 ) {
ERROR_SEVERITY errorSeverity;
rv = HalpGetStateInfo( MCA_EVENT, mcaLog );
salStatus = rv.ReturnValues[0];
switch( salStatus ) {
case SAL_STATUS_SUCCESS:
errorSeverity = HalpMcaProcessLog( mcaLog );
if ( errorSeverity == ErrorFatal ) {
//
// We are now going down with a MACHINE_CHECK_EXCEPTION.
// No return...
//
HalpMcaBugCheck( HAL_BUGCHECK_MCA_FATAL, mcaLog,
mcaAllocatedLogSize,
0 );
}
rv = HalpClearStateInfo( MCA_EVENT );
if ( !SAL_SUCCESSFUL(rv) ) {
//
// Current consideration for this implementation - 08/2000:
// if clearing the event fails, we assume that FW has a real problem;
// continuing will be dangerous. We bugcheck.
//
HalpMcaBugCheck( HAL_BUGCHECK_MCA_CLEAR_STATEINFO, mcaLog,
mcaAllocatedLogSize,
rv.ReturnValues[0] );
}
// SAL_STATUS_SUCCESS, SAL_STATUS_SUCCESS_MORE_RECORDS ... and
// ErrorSeverity != ErrorFatal.
//
// Call the registered kernel handler.
//
// Thierry 08/2000 - FIXFIX:
// The errorSeverity check is under comments. It should not be commented for the
// final version. However, we wanted to have kernel notification if we are getting
// log error severity != ErrorFatal or != ErrorRecoverable.
if ( /* (errorSeverity == ErrorCorrected) && */
( HalpMcaInfo.KernelDelivery || HalpMcaInfo.DriverInfo.DpcCallback ) ) {
InterlockedExchange( &HalpMcaInfo.DpcNotification, 1 );
}
break;
case SAL_STATUS_NO_INFORMATION_AVAILABLE:
//
// The salStatus value will break the salStatus loop.
//
rv.ReturnValues[0] = SAL_STATUS_SUCCESS;
break;
case SAL_STATUS_SUCCESS_WITH_OVERFLOW:
case SAL_STATUS_INVALID_ARGUMENT:
case SAL_STATUS_ERROR:
case SAL_STATUS_VA_NOT_REGISTERED:
default: // Thierry 08/00: WARNING - SAL July 2000 - v2.90.
// default includes possible unknown positive salStatus values.
HalpMcaBugCheck( HAL_BUGCHECK_MCA_GET_STATEINFO, mcaLog,
mcaAllocatedLogSize,
salStatus );
break;
}
}
//
// Currently 08/2000, we do not support the modification of the minstate.
//
mcaResources->OsToSalHandOff.MinStateSavePtr = mcaResources->SalToOsHandOff.MinStateSavePtr;
mcaResources->OsToSalHandOff.Result = rv.ReturnValues[0];
//
// If error was corrected and MCA non-monarch processors are in rendez vous,
// we will have to wake them up.
//
mcWakeUp = ( (rv.ReturnValues[0] == SAL_STATUS_SUCCESS) &&
HalpSalRendezVousSucceeded( mcaResources->SalToOsHandOff ) );
//
// Release MCA spinlock protecting OS_MCA resources.
//
HalpOsMcaInProgress = 0;
HalpReleaseMcaSpinLock( &HalpMcaSpinLock );
//
// If required, let's wake MCA non-monarch processors up.
//
if ( mcWakeUp ) {
HalpMcWakeUp();
}
return( rv );
} // HalpMcaHandler()
//++
// Name: HalpGetErrLogSize()
//
// Routine Description:
//
// This is a wrapper that will call SAL_GET_STATE_INFO_SIZE
//
// Arguments On Entry:
// arg0 = Reserved
// arg1 = Event Type (MCA,INIT,CMC,CPE)
//
// Returns
// rtn0=Success/Failure (0/!0)
// rtn1=Size
//--
SAL_PAL_RETURN_VALUES
HalpGetErrLogSize( ULONGLONG Res,
ULONGLONG eType
)
{
SAL_PAL_RETURN_VALUES rv = {0};
HalpSalCall(SAL_GET_STATE_INFO_SIZE, eType, 0,0,0,0,0,0, &rv);
return(rv);
}
//EndProc//////////////////////////////////////////////////////////////////////
//++
// Name: HalpGetErrLog()
//
// Routine Description:
//
// This is a wrapper that will call SAL_GET_STATE_INFO
//
// Arguments On Entry:
// arg0 = Reserved
// arg1 = Event Type (MCA,INIT,CMC)
// arg3 = pBuffer
//
// Success/Failure (0/!0)
//--
SAL_PAL_RETURN_VALUES
HalpGetErrLog( ULONGLONG Res,
ULONGLONG eType,
ULONGLONG* pBuff
)
{
SAL_PAL_RETURN_VALUES rv={0};
HalpSalCall(SAL_GET_STATE_INFO, eType, 0, (ULONGLONG)pBuff, 0,0,0,0, &rv);
//
// Regardless of the call success or failure, fix the record to store
// the processor number the SAL_PROC was executed on.
// This feature is requested by WMI.
//
HalpSetFwMceLogProcessorNumber( (PERROR_RECORD_HEADER)pBuff );
return(rv);
}
//EndProc//////////////////////////////////////////////////////////////////////
//++
// Name: HalpClrErrLog()
//
// Routine Description:
//
// This is a wrapper that will call SAL_CLEAR_STATE_INFO
//
// Arguments On Entry:
// arg0 = Reserved
// arg1 = Event Type (MCA,INIT,CMC,CPE)
//
// Success/Failure (0/!0)
//--
SAL_PAL_RETURN_VALUES
HalpClrErrLog( ULONGLONG Res,
ULONGLONG eType
)
{
SAL_PAL_RETURN_VALUES rv={0};
HalpSalCall( SAL_CLEAR_STATE_INFO, eType, 0,0,0,0,0,0, &rv );
return(rv);
}
//EndProc//////////////////////////////////////////////////////////////////////
//++
// Name: HalpSalSetParams()
//
// Routine Description:
//
// This is a wrapper that will call SAL_MC_SET_PARAMS
//
// Arguments On Entry:
// arg0 = Reserved
// arg1 = Parameter Type (rendz. or wakeup)
// arg2 = Event Type (interrupt/semaphore)
// arg3 = Interrupt Vector or Memory Address
// arg4 = Timeout value for rendezvous
//
// Success/Failure (0/!0)
//--
SAL_PAL_RETURN_VALUES
HalpSalSetParams(ULONGLONG Res,
ULONGLONG pType,
ULONGLONG eType,
ULONGLONG VecAdd,
ULONGLONG tValue)
{
SAL_PAL_RETURN_VALUES rv={0};
HalpSalCall(SAL_MC_SET_PARAMS, pType, eType, VecAdd,tValue,0,0,0,&rv);
return(rv);
}
//EndProc//////////////////////////////////////////////////////////////////////
//++
// Name: HalpSalSetVectors()
//
// Routine Description:
//
// This is a wrapper that will call SAL_SET_VECTORS
//
// Arguments On Entry:
// arg0 = Reserved
// arg1 = Event Type (MCA, INIT..)
// arg2 = Physical Address of handler
// arg3 = gp
// arg4 = length of event handler in bytes
//
// Success/Failure (0/!0)
//--
SAL_PAL_RETURN_VALUES
HalpSalSetVectors( ULONGLONG Res,
ULONGLONG eType,
PHYSICAL_ADDRESS Addr,
ULONGLONG gpValue,
ULONGLONG szHndlr)
{
SAL_PAL_RETURN_VALUES rv={0};
if ( eType == InitEvent ) {
//
// Thierry 08/2000:
// Current implementation assumes that OS decides the monarch inside OS_INIT.
// This implies handler_2, gp_2, length_2 are identical to handler_1, gp_1, length_1.
//
HalpSalCall(SAL_SET_VECTORS, eType, (ULONGLONG)Addr.QuadPart, gpValue, szHndlr,
(ULONGLONG)Addr.QuadPart, gpValue, szHndlr, &rv);
}
else {
HalpSalCall(SAL_SET_VECTORS, eType, (ULONGLONG)Addr.QuadPart, gpValue,szHndlr,0,0,0,&rv);
}
return(rv);
}
//EndProc//////////////////////////////////////////////////////////////////////
//++
// Name: HalpSalRendz()
//
// Routine Description:
//
// This is a wrapper that will call SAL_MC_RENDEZ
//
// Arguments On Entry:
// arg0 = Reserved
//
// Success/Failure (0/!0)
//--
SAL_PAL_RETURN_VALUES
HalpSalRendz(void)
{
SAL_PAL_RETURN_VALUES rv={0};
HalpSalCall(SAL_MC_RENDEZ, 0, 0, 0,0,0,0,0,&rv);
return(rv);
}
VOID
HalpMcWakeUp(
VOID
)
/*++
Routine Description:
This function does IPI to wakeup the MC non-monarch processors.
Arguments:
None.
Return Value:
None.
Remarks:
This function is assumed to be executed on the MC monarch processor.
--*/
{
USHORT LogicalCpu;
USHORT ProcessorID;
USHORT monarchID;
//
// Scan the processor set and request an interprocessor interrupt on
// each of the specified targets.
//
monarchID = (USHORT)PCR->HalReserved[PROCESSOR_ID_INDEX];
for (LogicalCpu = 0; LogicalCpu < HalpMpInfo.ProcessorCount; LogicalCpu++) {
//
// Only IPI processors that are started.
//
if (HalpActiveProcessors & (1 << HalpProcessorInfo[LogicalCpu].NtProcessorNumber)) {
ProcessorID = HalpProcessorInfo[LogicalCpu].LocalApicID;
//
// Request interprocessor interrupt on target physicalCpu.
//
if ( ProcessorID != monarchID ) {
HalpSendIPI(ProcessorID, MC_WKUP_VECTOR);
}
}
}
} // HalpMcWakeUp()
VOID
HalpCMCEnable(
VOID
)
/*++
Routine Description:
This routine sets the processor CMCV register with CMCI_VECTOR.
Arguments:
None.
Return Value:
None.
--*/
{
if ( HalpFeatureBits & HAL_CMC_PRESENT ) {
HalpWriteCMCVector( CMCI_VECTOR );
}
return;
} // HalpCMCEnable()
VOID
HalpCMCDisable(
VOID
)
/*++
Routine Description:
This routine resets the processor CMCV register.
Arguments:
None
Return Value:
None
--*/
{
HalpWriteCMCVector( 0x10000ui64 );
return;
} // HalpCMCDisable()
ULONG_PTR
HalpSetCMCVector(
IN ULONG_PTR CmcVector
)
/*++
Routine Description:
This routine sets the processor CMCV register with specified vector.
This function is the broadcast function for HalpCMCDisableForAllProcessors().
Arguments:
CmcVector: CMC Vector value.
Value:
STATUS_SUCCESS
--*/
{
HalpWriteCMCVector( (ULONG64)CmcVector );
return((ULONG_PTR)(ULONG)(STATUS_SUCCESS));
} // HalpSetCmcVector()
VOID
HalpCMCDisableForAllProcessors(
VOID
)
/*++
Routine Description:
This routine disables processor CMC on every processor in the host configuration
by executing HalpSetCmcVector( 0ui64 ) on every processor in a synchronous manner.
Arguments:
None.
Value:
None.
--*/
{
//
// Can not do an IPI if the processors are above IPI level such
// as we are in the kernel debugger.
//
if (KeGetCurrentIrql() < IPI_LEVEL) {
(VOID)KiIpiGenericCall( HalpSetCMCVector, (ULONG_PTR)0x10000ui64 );
} else {
HalpSetCMCVector(0x10000ui64);
}
return;
} // HalpCMCDisableForAllProcessors()
VOID
HalpCMCIHandler (
IN PKINTERRUPT_ROUTINE Interrupt,
IN PKTRAP_FRAME TrapFrame
)
/*++
Routine Description:
Processor Interrupt routine for CMC interrupts.
Arguments:
TrapFrame - Captured trap frame address.
Return Parameters:
None.
Notes:
Thierry 08/2000:
This function does not do much, it flags the PCR InOsCmc field
and calls the second-level handler: HalpCmcHandler().
However, this was implmented this way so this function abstracts the
standard interrupts resources from the purely CMC processing in HalpCmcHandler().
--*/
{
volatile KPCR * const pcr = KeGetPcr();
pcr->InOsCmc = TRUE;
HalpCmcHandler();
pcr->InOsCmc = FALSE;
return;
} // HalpCMCIHandler()
VOID
HalpCmcProcessLog(
PCMC_EXCEPTION CmcLog
)
/*++
Routine Description:
This function does a simple processing check a IA64 CMC log.
Arguments:
CmcLog - Provides CMC log address
Return Parameters:
None.
Notes:
Currently simply checking and outputing log contents for checked hal only.
--*/
{
#if DBG
//
// Simple log processing for first debugging...
//
GUID processorDeviceGuid = ERROR_PROCESSOR_GUID;
BOOLEAN processorDeviceFound;
PERROR_RECORD_HEADER header = (PERROR_RECORD_HEADER)CmcLog;
PERROR_SECTION_HEADER section, sectionMax;
if ( header->ErrorSeverity != ErrorCorrected ) {
HalDebugPrint(( HAL_ERROR,
"HAL!HalpCmcProcessLog: CMC record with severity [%d] != corrected!!!\n",
header->ErrorSeverity ));
}
//
// SAL spec BUGBUG 08/2000: we should have put the length of the header in the definition.
// Same for section header.
//
processorDeviceFound = FALSE;
section = (PERROR_SECTION_HEADER)((ULONG_PTR)header + sizeof(*header));
sectionMax = (PERROR_SECTION_HEADER)((ULONG_PTR)header + header->Length);
while( section < sectionMax ) {
if ( IsEqualGUID( &section->Guid, &processorDeviceGuid ) ) {
PERROR_PROCESSOR processorRecord = (PERROR_PROCESSOR)section;
processorDeviceFound = TRUE;
//
// Minimum processing here. This will enhance with testing and most common
// occurences.
//
if ( processorRecord->Valid.StateParameter ) {
ULONGLONG stateParameter = processorRecord->StateParameter.StateParameter;
//
// At any time more than one error could be valid
//
if((stateParameter >> ERROR_PROCESSOR_STATE_PARAMETER_CACHE_CHECK_SHIFT) &
ERROR_PROCESSOR_STATE_PARAMETER_CACHE_CHECK_MASK) {
//
// cache error
//
HalDebugPrint(( HAL_INFO,
"HAL!HalpCmcProcessLog: Corrected Processor CACHE Machine Check error\n" ));
}
if((stateParameter >> ERROR_PROCESSOR_STATE_PARAMETER_TLB_CHECK_SHIFT) &
ERROR_PROCESSOR_STATE_PARAMETER_TLB_CHECK_MASK) {
//
// tlb error
//
HalDebugPrint(( HAL_INFO,
"HAL!HalpCmcProcessLog: Corrected Processor TLB Machine Check error\n" ));
}
if((stateParameter >> ERROR_PROCESSOR_STATE_PARAMETER_BUS_CHECK_SHIFT) &
ERROR_PROCESSOR_STATE_PARAMETER_BUS_CHECK_MASK) {
//
// bus error
//
HalDebugPrint(( HAL_INFO,
"HAL!HalpCmcProcessLog: Corrected Processor BUS Machine Check error\n" ));
}
if((stateParameter >> ERROR_PROCESSOR_STATE_PARAMETER_UNKNOWN_CHECK_SHIFT) &
ERROR_PROCESSOR_STATE_PARAMETER_UNKNOWN_CHECK_MASK) {
//
// unknown error
//
HalDebugPrint(( HAL_INFO,
"HAL!HalpCmcProcessLog: Corrected Processor UNKNOWN Machine Check error\n" ));
}
}
}
}
if ( !processorDeviceFound ) {
HalDebugPrint(( HAL_ERROR,
"HAL!HalpCmcProcessLog: CMC log without processor device record!!!\n"));
}
#endif // DBG
return;
} // HalpCmcProcessLog()
//++
// Name: HalpCmcHandler()
//
// Routine Description:
//
// This is the second level CMC Interrupt Handler for FW corrected errors.
//
// Arguments On Entry:
// None.
//
// Return.
// None.
//
// Notes:
// This function calls the kernel notification and inserts the OEM CMC driver dpc if
// registered.
// Accessing the CMC logs at this level could be inacceptable because of the possible
// large size of the logs and the time required to collect them.
// The collection of the logs is delayed until the work item calls
// HalQuerySystemInformation.HalCmcLogInformation.
//--
VOID
HalpCmcHandler(
VOID
)
{
//
// Internal housekeeping.
//
InterlockedIncrement( &HalpCmcInfo.Stats.CmcInterruptCount );
//
// Notify the kernel if registered.
//
if ( HalpCmcInfo.KernelDelivery ) {
if ( !HalpCmcInfo.KernelDelivery( HalpCmcInfo.KernelToken, NULL ) ) {
InterlockedIncrement( &HalpCmcInfo.Stats.KernelDeliveryFails );
}
}
//
// Notify the OEM CMC driver if registered.
//
if ( HalpCmcInfo.DriverInfo.DpcCallback ) {
if ( !KeInsertQueueDpc( &HalpCmcInfo.DriverDpc, NULL, NULL ) ) {
InterlockedIncrement( &HalpCmcInfo.Stats.DriverDpcQueueFails );
}
}
return;
} // HalpCmcHandler()
//EndProc//////////////////////////////////////////////////////////////////////
//++
// Name: HalpCpeHandler()
//
// Routine Description:
//
// This is the second level CPE Interrupt Handler for Platform corrected errors.
//
// Arguments On Entry:
// None.
//
// Return.
// None.
//
// Notes:
// This function calls the kernel notification and inserts the OEM CPE driver dpc if
// registered.
// Accessing the CPE logs at this level could be inacceptable because of the possible
// large size of the logs and the time required to collect them.
// The collection of the logs is delayed until the work item calls
// HalQuerySystemInformation.HalCpeLogInformation.
//--
VOID
HalpCpeHandler(
VOID
)
{
//
// Internal housekeeping.
//
InterlockedIncrement( &HalpCpeInfo.Stats.CpeInterruptCount );
//
// Notify the kernel if registered.
//
if ( HalpCpeInfo.KernelDelivery ) {
if ( !HalpCpeInfo.KernelDelivery( HalpCpeInfo.KernelToken, NULL ) ) {
InterlockedIncrement( &HalpCpeInfo.Stats.KernelDeliveryFails );
}
}
//
// Notify the OEM CPE driver if registered.
//
if ( HalpCpeInfo.DriverInfo.DpcCallback ) {
if ( !KeInsertQueueDpc( &HalpCpeInfo.DriverDpc, NULL, NULL ) ) {
InterlockedIncrement( &HalpCpeInfo.Stats.DriverDpcQueueFails );
}
}
return;
} // HalpCpeHandler()
//EndProc//////////////////////////////////////////////////////////////////////
VOID
HalpMcRzHandler (
IN PKINTERRUPT_ROUTINE Interrupt,
IN PKTRAP_FRAME TrapFrame
)
/*++
Routine Description:
Arguements:
Return Parameters:
--*/
{
SAL_PAL_RETURN_VALUES rv={0};
HalpDisableInterrupts();
rv=HalpSalRendz();
HalpEnableInterrupts();
// do any Isr clean up and re-enable the interrupts & MC's
return;
}
//EndProc//////////////////////////////////////////////////////////////////////
VOID
HalpMcWkupHandler (
IN PKINTERRUPT_ROUTINE Interrupt,
IN PKTRAP_FRAME TrapFrame
)
/*++
Routine Description:
Arguements:
Return Parameters:
--*/
{
return;
}
//EndProc//////////////////////////////////////////////////////////////////////
VOID
HalpCPEIHandler (
IN PKINTERRUPT_ROUTINE Interrupt,
IN PKTRAP_FRAME TrapFrame
)
/*++
Routine Description:
Processor Interrupt routine for CPE interrupts.
Arguments:
TrapFrame - Captured trap frame address.
Return Parameters:
None.
Notes:
Thierry 08/2000:
This function does not do much, it flags the PCR InOsCpe field
and calls the second-level handler: HalpCpeHandler().
However, this was implmented this way so this function abstracts the
standard interrupts resources from the purely CPE processing in HalpCpeHandler().
--*/
{
volatile KPCR * const pcr = KeGetPcr();
pcr->InOsCpe = TRUE;
HalpCpeHandler();
pcr->InOsCpe = FALSE;
return;
} // HalpCPEIHandler()
VOID
HalpCPEEnable (
VOID
)
/*++
Routine Description:
This routine sets the default HAL CPE handling regardless of the user specified
registry setting. It enables the supported Platform Interrupt sources and
exposes the initial interrupt/polling based mode used for CPE.
The user specified registry setting is handled via HalpMcaInit() at the end of
phase 1.
Arguments:
None.
Return Parameters:
None.
Implementation Notes:
The following implementation assumes that this code is executed on BSP.
--*/
{
ULONG i;
if ( HalpFeatureBits & HAL_CPE_PRESENT ) {
ULONG maxCPE = HalpMaxCPEImplemented;
if ( maxCPE ) {
//
// Pick up the information from HalpCPEIntIn, HalpCPEDestination, HalpCPEVectorFlags,
// HalpCPEIoSapicVector.
//
for (i=0 ; i != maxCPE; i++ ) {
HalpEnableRedirEntry( HalpCPEIntIn[i] );
}
//
// Initialize the remaining fields of HAL private CPE info structure.
//
HalpCpeInfo.Stats.PollingInterval = HAL_CPE_INTERRUPTS_BASED;
}
else {
//
// We will implement Polling model.
//
//
// Thierry 03/11/2001: WARNING WARNING
// Do not enable xxhal.c HAL_CPE_PRESENT if HalpMaxCPEImplemented == 0.
// We bugcheck with the current BigSur SAL/FW (<= build 99) at SAL_GET_STATE_INFO calls,
// the FW assuming that we are calling the SAL MC related functions in physical mode.
// With the Lion SAL/FW (<= build 75), we bugcheck after getting MCA logs at boot time,
// the FW having some virtualization issues.
// Intel is committed to provide working FWs soon (< 2 weeks...).
//
HalpCpeInfo.Stats.PollingInterval = HALP_CPE_DEFAULT_POLLING_INTERVAL;
}
}
else {
HalpCpeInfo.Stats.PollingInterval = HAL_CPE_DISABLED;
}
return;
} // HalpCPEEnable()
VOID
HalpCPEDisable (
VOID
)
/*++
Routine Description:
This routine disables the SAPIC Platform Interrupt Sources.
Note that if HalpMaxCPEImplemented is 0, the function does nothing.
Arguments:
None.
Return Parameters:
None.
--*/
{
//
// Pick up the information from HalpCPEIntIn, HalpCPEDestination, HalpCPEVectorFlags,
// HalpCPEIoSapicVector
int i;
for (i=0;i != HalpMaxCPEImplemented;i++) {
HalpDisableRedirEntry(HalpCPEIntIn[i]);
}
return;
} // HalpCPEDisable()
VOID
HalpMCADisable(
VOID
)
{
PHYSICAL_ADDRESS NULL_PHYSICAL_ADDRESS = {0};
SAL_PAL_RETURN_VALUES rv = {0};
char Lid;
ULONGLONG gp_reg = GetGp();
// Disable CMCs
HalpCMCDisableForAllProcessors();
// Disable CPE Interrupts
HalpCPEDisable();
//DeRegister Rendez. Paramters with SAL
#define NULL_VECTOR 0xF
rv = HalpSalSetParams(0,RendzType, IntrVecType, NULL_VECTOR, HalpMcRendezTimeOut );
// Deregister WakeUp parameters with SAL
rv=HalpSalSetParams(0, WakeUpType, IntrVecType, NULL_VECTOR,0);
// Deregister OsMcaDispatch (OS_MCA) physical address with SAL
rv=HalpSalSetVectors(0, MchkEvent, NULL_PHYSICAL_ADDRESS, gp_reg,0);
// Deregister OsInitDispatch physical address with SAL
rv=HalpSalSetVectors(0, InitEvent, NULL_PHYSICAL_ADDRESS, gp_reg,0);
return;
} // HalpMCADisable()
NTSTATUS
HalpGetMceInformation(
PHAL_ERROR_INFO ErrorInfo,
PULONG ErrorInfoLength
)
/*++
Routine Description:
This routine is called by HaliQuerySystemInformation for the HalErrorInformation class.
Arguments:
ErrorInfo : pointer to HAL_ERROR_INFO structure.
ErrorInfoLength : size of the valid memory structure pointed by ErrorInfo.
Return Value:
STATUS_SUCCESS if successful
error status otherwise
--*/
{
NTSTATUS status;
ULONG cpePollingInterval;
PAGED_CODE();
ASSERT( ErrorInfo );
ASSERT( ErrorInfoLength );
//
// Backward compatibility only.
//
if ( !ErrorInfo->Version || ( ErrorInfo->Version > HAL_ERROR_INFO_VERSION ) ) {
return( STATUS_REVISION_MISMATCH );
}
//
// Zero Reserved field.
//
ErrorInfo->Reserved = 0;
//
// Collect MCA info under protection if required.
//
ErrorInfo->McaMaxSize = HalpMcaInfo.Stats.MaxLogSize;
ErrorInfo->McaPreviousEventsCount = HalpMcaInfo.Stats.McaPreviousCount;
ErrorInfo->McaCorrectedEventsCount = HalpMcaInfo.Stats.McaCorrectedCount; // approximation.
ErrorInfo->McaKernelDeliveryFails = HalpMcaInfo.Stats.KernelDeliveryFails; // approximation.
ErrorInfo->McaDriverDpcQueueFails = HalpMcaInfo.Stats.DriverDpcQueueFails; // approximation.
ErrorInfo->McaReserved = 0;
//
// Collect CMC info under protection if required.
//
ErrorInfo->CmcMaxSize = HalpCmcInfo.Stats.MaxLogSize;
ErrorInfo->CmcPollingInterval = HalpCmcInfo.Stats.PollingInterval;
ErrorInfo->CmcInterruptsCount = HalpCmcInfo.Stats.CmcInterruptCount; // approximation.
ErrorInfo->CmcKernelDeliveryFails = HalpCmcInfo.Stats.KernelDeliveryFails; // approximation.
ErrorInfo->CmcDriverDpcQueueFails = HalpCmcInfo.Stats.DriverDpcQueueFails; // approximation.
HalpAcquireCmcMutex();
ErrorInfo->CmcGetStateFails = HalpCmcInfo.Stats.GetStateFails;
ErrorInfo->CmcClearStateFails = HalpCmcInfo.Stats.ClearStateFails;
ErrorInfo->CmcLogId = HalpCmcInfo.Stats.LogId;
HalpReleaseCmcMutex();
ErrorInfo->CmcReserved = 0;
//
// Collect CPE info under protection if required.
//
ErrorInfo->CpeMaxSize = HalpCpeInfo.Stats.MaxLogSize;
ErrorInfo->CpePollingInterval = HalpCpeInfo.Stats.PollingInterval;
ErrorInfo->CpeInterruptsCount = HalpCpeInfo.Stats.CpeInterruptCount; // approximation.
ErrorInfo->CpeKernelDeliveryFails = HalpCpeInfo.Stats.KernelDeliveryFails; // approximation.
ErrorInfo->CpeDriverDpcQueueFails = HalpCpeInfo.Stats.DriverDpcQueueFails; // approximation.
HalpAcquireCpeMutex();
ErrorInfo->CpeGetStateFails = HalpCpeInfo.Stats.GetStateFails;
ErrorInfo->CpeClearStateFails = HalpCpeInfo.Stats.ClearStateFails;
ErrorInfo->CpeLogId = HalpCpeInfo.Stats.LogId;
HalpReleaseCpeMutex();
// CpeInterruptSources: Number of SAPIC Platform Interrup Sources supported by HAL.
ErrorInfo->CpeInterruptSources = HalpMaxCPEImplemented;
//
// Update KernelTokens
//
ErrorInfo->McaKernelToken = (ULONGLONG) HalpMcaInfo.KernelToken;
ErrorInfo->CmcKernelToken = (ULONGLONG) HalpCmcInfo.KernelToken;
ErrorInfo->CpeKernelToken = (ULONGLONG) HalpCpeInfo.KernelToken;
ErrorInfo->KernelReserved[3] = (ULONGLONG) 0;
*ErrorInfoLength = sizeof(*ErrorInfo);
return( STATUS_SUCCESS );
} // HalpGetMceInformation()