/*++ Copyright (c) 1997 Microsoft Corporation Module Name: xxacpi.c Abstract: Implements various ACPI utility functions. Author: Jake Oshins (jakeo) 12-Feb-1997 Environment: Kernel mode only. Revision History: Todd Kjos (HP) (v-tkjos) 1-Jun-1998 : Added IA64 support --*/ #include "halp.h" #include "acpitabl.h" #include "xxacpi.h" #include "pci.h" //#define DUMP_FADT VOID HalAcpiTimerCarry( VOID ); VOID HalaAcpiTimerInit( #if defined(ACPI64) ULONG_PTR TimerPort, #else ULONG TimerPort, #endif BOOLEAN TimerValExt ); ULONG HaliAcpiQueryFlags( VOID ); VOID HaliAcpiTimerInit( // *** TBD should be ULONG_PTR ULONG TimerPort OPTIONAL, IN BOOLEAN TimerValExt ); VOID HaliAcpiMachineStateInit( IN PPROCESSOR_INIT ProcInit, IN PHAL_SLEEP_VAL SleepValues, OUT PULONG PicVal ); BOOLEAN FASTCALL HalAcpiC1Idle( OUT PPROCESSOR_IDLE_TIMES IdleTimes ); BOOLEAN FASTCALL HalAcpiC2Idle( OUT PPROCESSOR_IDLE_TIMES IdleTimes ); BOOLEAN FASTCALL HalAcpiC3ArbdisIdle( OUT PPROCESSOR_IDLE_TIMES IdleTimes ); BOOLEAN FASTCALL HalAcpiC3WbinvdIdle( OUT PPROCESSOR_IDLE_TIMES IdleTimes ); VOID FASTCALL HalProcessorThrottle( IN UCHAR Throttle ); NTSTATUS HaliSetWakeAlarm ( IN ULONGLONG WakeSystemTime, IN PTIME_FIELDS WakeTimeFields OPTIONAL ); VOID HaliSetWakeEnable( IN BOOLEAN Enable ); VOID HalpSetInterruptControllerWakeupState( ULONG Context ); PVOID HalpRemapVirtualAddress( IN PVOID VirtualAddress, IN PVOID PhysicalAddress, IN BOOLEAN WriteThrough ); ULONG HaliPciInterfaceReadConfig( IN PVOID Context, IN UCHAR BusOffset, IN ULONG Slot, IN PVOID Buffer, IN ULONG Offset, IN ULONG Length ); ULONG HaliPciInterfaceWriteConfig( IN PVOID Context, IN UCHAR BusOffset, IN ULONG Slot, IN PVOID Buffer, IN ULONG Offset, IN ULONG Length ); VOID HalpNumaInitializeStaticConfiguration( IN PLOADER_PARAMETER_BLOCK ); // // HAL Hack flags // typedef enum { HalHackAddFakeSleepHandlersS1 = 1, HalHackAddFakeSleepHandlersS2 = 2, HalHackAddFakeSleepHandlersS3 = 4 } HALHACKFLAGS; extern HALHACKFLAGS HalpHackFlags = 0; // // Externs // extern ULONG HalpAcpiFlags; extern PHYSICAL_ADDRESS HalpAcpiRsdt; extern SLEEP_STATE_CONTEXT HalpShutdownContext; extern ULONG HalpPicVectorRedirect[]; // // Globals // ULONG HalpInvalidAcpiTable; PRSDT HalpAcpiRsdtVA; PXSDT HalpAcpiXsdtVA; PIPPT_TABLE HalpPlatformPropertiesTable; ULONG HalpPlatformPropertiesEfiFlags = 0; // IPPT Flags coming from EFI MDs // // This is the dispatch table used by the ACPI driver // HAL_ACPI_DISPATCH_TABLE HalAcpiDispatchTable; PPM_DISPATCH_TABLE PmAcpiDispatchTable = NULL; NTSTATUS HalpQueryAcpiResourceRequirements( IN PIO_RESOURCE_REQUIREMENTS_LIST *Requirements ); NTSTATUS HalpBuildAcpiResourceList( OUT PIO_RESOURCE_REQUIREMENTS_LIST List ); NTSTATUS HalpAcpiDetectResourceListSize( OUT PULONG ResourceListSize ); VOID HalpRestoreInterruptControllerState( VOID ); ULONG HalpGetPCIData ( IN PBUS_HANDLER BusHandler, IN PBUS_HANDLER RootHandler, IN PCI_SLOT_NUMBER SlotNumber, IN PVOID Buffer, IN ULONG Offset, IN ULONG Length ); VOID HalpReadRegistryAndApplyHacks ( VOID ); #define LOW_MEMORY 0x000100000 #define MAX(a, b) \ ((a) > (b) ? (a) : (b)) #define MIN(a, b) \ ((a) < (b) ? (a) : (b)) // ADRIAO 01/12/98 - We no longer having the HAL declare the IO ports // specified in the FADT. These will be declared in a future // defined PNP0Cxx node (for new, in PNP0C02). This is done // because we cannot know at the hal level what bus the ACPI // FADT resources refer to. We can only the translated resource info. // Hence.... #define DECLARE_FADT_RESOURCES_AT_ROOT 0 #ifdef ALLOC_PRAGMA #pragma alloc_text(INIT, HalpGetAcpiTablePhase0) #pragma alloc_text(INIT, HalpSetupAcpiPhase0) #pragma alloc_text(PAGE, HaliInitPowerManagement) #pragma alloc_text(PAGE, HalpQueryAcpiResourceRequirements) #pragma alloc_text(PAGE, HalpBuildAcpiResourceList) #pragma alloc_text(PAGE, HalpGetCrossPartitionIpiInterface) #pragma alloc_text(PAGE, HalpAcpiDetectResourceListSize) #pragma alloc_text(PAGE, HalpReadRegistryAndApplyHacks) #pragma alloc_text(PAGE, HaliAcpiTimerInit) #pragma alloc_text(PAGE, HaliAcpiMachineStateInit) #pragma alloc_text(PAGE, HaliAcpiQueryFlags) #pragma alloc_text(PAGE, HaliSetWakeEnable) #endif PVOID HalpGetAcpiTablePhase0( IN PLOADER_PARAMETER_BLOCK LoaderBlock, IN ULONG Signature ) /*++ Routine Description: This function returns a pointer to the ACPI table that is identified by Signature. Arguments: Signature - A four byte value that identifies the ACPI table Return Value: Pointer to a copy of the table --*/ { PRSDT rsdt; PXSDT xsdt; ULONG entry, rsdtEntries; PVOID table; PHYSICAL_ADDRESS physicalAddr; PDESCRIPTION_HEADER header; NTSTATUS status; ULONG lengthInPages; ULONG offset; // // unless we get the exceptional case where the platform identifies that // ACPI tables must be explicitly mapped cached, we map the ACPI tables // noncached. We are relying on the first mapping of this range to have // the "correct" caching flag, as that is the cachability attribute that // all subsequent mappings of this range (ie., mapping of additional data // in the same page from ACPI driver for a memory operation region, etc.). // This semantic is enforced by the memory manager. // MEMORY_CACHING_TYPE acpiTableMappingType = (HalpPlatformPropertiesEfiFlags & HAL_PLATFORM_ACPI_TABLES_CACHED) ? MmCached : MmNonCached; physicalAddr.QuadPart = 0; header = NULL; if ((HalpAcpiRsdtVA == NULL) && (HalpAcpiXsdtVA == NULL)) { // // Find and map the RSDT once. This mapping is reused on // subsequent calls to this routine. // status = HalpAcpiFindRsdtPhase0(LoaderBlock); if (!(NT_SUCCESS(status))) { HalDebugPrint(( HAL_INFO, "HAL: *** make sure you are using ntdetect.com v5.0 ***\n" )); KeBugCheckEx(MISMATCHED_HAL, 4, 0xac31, 0, 0); } xsdt = HalpMapPhysicalMemory(HalpAcpiRsdt, 2, acpiTableMappingType ); if (!xsdt) { return NULL; } // // Do a sanity check on the RSDT. // if ((xsdt->Header.Signature != RSDT_SIGNATURE) && (xsdt->Header.Signature != XSDT_SIGNATURE)) { HalDisplayString("HAL: Bad RSDT pointer\n"); KeBugCheckEx(MISMATCHED_HAL, 4, 0xac31, 1, 0); } // // Remap the (X)RSDT now that we know how long it is. // offset = HalpAcpiRsdt.LowPart & (PAGE_SIZE - 1); lengthInPages = (offset + xsdt->Header.Length + (PAGE_SIZE - 1)) >> PAGE_SHIFT; if (lengthInPages != 2) { HalpUnmapVirtualAddress(xsdt, 2); xsdt = HalpMapPhysicalMemory(HalpAcpiRsdt, lengthInPages, acpiTableMappingType ); if (!xsdt) { DbgPrint("HAL: Couldn't remap RSDT\n"); return NULL; } } if (xsdt->Header.Signature == XSDT_SIGNATURE) { HalpAcpiXsdtVA = xsdt; } else { HalpAcpiRsdtVA = (PRSDT)xsdt; HalpAcpiXsdtVA = NULL; } } xsdt = HalpAcpiXsdtVA; rsdt = HalpAcpiRsdtVA; rsdtEntries = xsdt ? NumTableEntriesFromXSDTPointer(xsdt) : NumTableEntriesFromRSDTPointer(rsdt); // // Look down the pointer in each entry to see if it points to // the table we are looking for. // for (entry = 0; entry < rsdtEntries; entry++) { physicalAddr.QuadPart = xsdt ? xsdt->Tables[entry].QuadPart : rsdt->Tables[entry]; if (header != NULL) { HalpUnmapVirtualAddress(header, 2); } header = HalpMapPhysicalMemory(physicalAddr, 2, acpiTableMappingType ); if (!header) { return NULL; } if (header->Signature == Signature) { break; } } if (entry == rsdtEntries) { // // Signature not found, free the PTR for the last entry // examined and indicate failure to the caller. // HalpUnmapVirtualAddress(header, 2); return NULL; } // // Make sure we have mapped enough memory to cover the entire // table. // offset = (ULONG)((ULONG_PTR)header & (PAGE_SIZE - 1)); lengthInPages = (header->Length + offset + (PAGE_SIZE - 1)) >> PAGE_SHIFT; if (lengthInPages != 2) { HalpUnmapVirtualAddress(header, 2); header = HalpMapPhysicalMemory( physicalAddr, lengthInPages, acpiTableMappingType ); } // // Validate the table's checksum. // N.B. We expect the checksum to be wrong on some early versions // of the FADT. // if ((header != NULL) && ((header->Signature != FADT_SIGNATURE) || (header->Revision > 2))) { PUCHAR c = (PUCHAR)header + header->Length; UCHAR s = 0; if (header->Length) { do { s += *--c; } while (c != (PUCHAR)header); } if ((s != 0) || (header->Length == 0)) { // // This table is not valid. // HalpInvalidAcpiTable = header->Signature; #if 0 // // Don't return this table. // HalpUnmapVirtualAddress(header, lengthInPages); return NULL; #endif } } return header; } NTSTATUS HalpSetupAcpiPhase0( IN PLOADER_PARAMETER_BLOCK LoaderBlock ) /*++ Routine Description: Save some information from the ACPI tables before they get destroyed. Arguments: none Return Value: none --*/ { NTSTATUS status; ULONG entry; PVOID table; PVOID physicalAddr; PDESCRIPTION_HEADER header; ULONG blkSize; PHYSICAL_ADDRESS rawAddr; // // Copy the Fixed Acpi Descriptor Table (FADT) to a permanent // home. // header = HalpGetAcpiTablePhase0(LoaderBlock, FADT_SIGNATURE); if (header == NULL) { HalDebugPrint(( HAL_INFO, "HAL: Didn't find the FACP\n" )); return STATUS_NOT_FOUND; } RtlCopyMemory(&HalpFixedAcpiDescTable, header, MIN(header->Length, sizeof(HalpFixedAcpiDescTable))); if (header->Revision < 3) { KeBugCheckEx(ACPI_BIOS_ERROR, 0x11, 9, header->Revision, 0); } // Check for MMIO addresses that need to be mapped. blkSize = HalpFixedAcpiDescTable.pm1_evt_len; ASSERT(blkSize); if ((HalpFixedAcpiDescTable.x_pm1a_evt_blk.AddressSpaceID == AcpiGenericSpaceMemory) && (blkSize > 0)) { rawAddr = HalpFixedAcpiDescTable.x_pm1a_evt_blk.Address; HalpFixedAcpiDescTable.x_pm1a_evt_blk.Address.QuadPart = (LONGLONG)HalpMapPhysicalMemory(rawAddr,ADDRESS_AND_SIZE_TO_SPAN_PAGES(rawAddr.LowPart, blkSize),MmNonCached); } blkSize = HalpFixedAcpiDescTable.pm1_ctrl_len; ASSERT(blkSize); if ((HalpFixedAcpiDescTable.x_pm1a_ctrl_blk.AddressSpaceID == AcpiGenericSpaceMemory) && (blkSize > 0)) { rawAddr = HalpFixedAcpiDescTable.x_pm1a_ctrl_blk.Address; HalpFixedAcpiDescTable.x_pm1a_ctrl_blk.Address.QuadPart = (LONGLONG) HalpMapPhysicalMemory(rawAddr,ADDRESS_AND_SIZE_TO_SPAN_PAGES(rawAddr.LowPart, blkSize),MmNonCached); } blkSize = HalpFixedAcpiDescTable.pm_tmr_len; ASSERT(blkSize); if ((HalpFixedAcpiDescTable.x_pm_tmr_blk.AddressSpaceID == AcpiGenericSpaceMemory) && (blkSize > 0)) { rawAddr = HalpFixedAcpiDescTable.x_pm_tmr_blk.Address; HalpFixedAcpiDescTable.x_pm_tmr_blk.Address.QuadPart = (LONGLONG) HalpMapPhysicalMemory(rawAddr,ADDRESS_AND_SIZE_TO_SPAN_PAGES(rawAddr.LowPart, blkSize),MmNonCached); } // The rest of these ACPI blocks are optional so test if they exist before mapping them if (HalpFixedAcpiDescTable.x_pm1b_evt_blk.Address.QuadPart) { if (HalpFixedAcpiDescTable.x_pm1b_evt_blk.AddressSpaceID == AcpiGenericSpaceMemory) { blkSize = HalpFixedAcpiDescTable.pm1_evt_len; rawAddr = HalpFixedAcpiDescTable.x_pm1b_evt_blk.Address; HalpFixedAcpiDescTable.x_pm1b_evt_blk.Address.QuadPart = (LONGLONG) HalpMapPhysicalMemory(rawAddr,ADDRESS_AND_SIZE_TO_SPAN_PAGES(rawAddr.LowPart, blkSize),MmNonCached); } } if (HalpFixedAcpiDescTable.x_pm1b_ctrl_blk.Address.QuadPart) { if (HalpFixedAcpiDescTable.x_pm1b_ctrl_blk.AddressSpaceID == AcpiGenericSpaceMemory) { blkSize = HalpFixedAcpiDescTable.pm1_ctrl_len; rawAddr = HalpFixedAcpiDescTable.x_pm1b_ctrl_blk.Address; HalpFixedAcpiDescTable.x_pm1b_ctrl_blk.Address.QuadPart = (LONGLONG) HalpMapPhysicalMemory(rawAddr,ADDRESS_AND_SIZE_TO_SPAN_PAGES(rawAddr.LowPart, blkSize),MmNonCached); } } if (HalpFixedAcpiDescTable.x_pm2_ctrl_blk.Address.QuadPart) { if (HalpFixedAcpiDescTable.x_pm2_ctrl_blk.AddressSpaceID == AcpiGenericSpaceMemory) { blkSize = HalpFixedAcpiDescTable.pm2_ctrl_len; rawAddr = HalpFixedAcpiDescTable.x_pm2_ctrl_blk.Address; HalpFixedAcpiDescTable.x_pm2_ctrl_blk.Address.QuadPart = (LONGLONG) HalpMapPhysicalMemory(rawAddr,ADDRESS_AND_SIZE_TO_SPAN_PAGES(rawAddr.LowPart, blkSize),MmNonCached); } } if (HalpFixedAcpiDescTable.x_gp0_blk.Address.QuadPart) { if (HalpFixedAcpiDescTable.x_gp0_blk.AddressSpaceID == AcpiGenericSpaceMemory) { blkSize = HalpFixedAcpiDescTable.gp0_blk_len; rawAddr = HalpFixedAcpiDescTable.x_gp0_blk.Address; HalpFixedAcpiDescTable.x_gp0_blk.Address.QuadPart = (LONGLONG) HalpMapPhysicalMemory(rawAddr,ADDRESS_AND_SIZE_TO_SPAN_PAGES(rawAddr.LowPart, blkSize),MmNonCached); } } if (HalpFixedAcpiDescTable.x_gp1_blk.Address.QuadPart) { if (HalpFixedAcpiDescTable.x_gp1_blk.AddressSpaceID == AcpiGenericSpaceMemory) { blkSize = HalpFixedAcpiDescTable.gp1_blk_len; rawAddr = HalpFixedAcpiDescTable.x_gp1_blk.Address; HalpFixedAcpiDescTable.x_gp1_blk.Address.QuadPart = (LONGLONG) HalpMapPhysicalMemory(rawAddr,ADDRESS_AND_SIZE_TO_SPAN_PAGES(rawAddr.LowPart, blkSize),MmNonCached); } } // // See if Static Resource Affinity Table is present. // HalpNumaInitializeStaticConfiguration(LoaderBlock); // // See if Windows Platform Properties Table is present. // HalpPlatformPropertiesTable = HalpGetAcpiTablePhase0(LoaderBlock, IPPT_SIGNATURE); // // Enable ACPI counter code since we need it in the boot // process. // HaliAcpiTimerInit(0, FALSE); // // Claim a page of memory below 1MB to be used for transitioning // a sleeping processor back from real mode to protected mode // #ifdef IA64 HalDebugPrint(( HAL_INFO, "HAL: WARNING - HalpSetupAcpi - Sleep transitions not yet implemented\n" )); #else // check first to see if this has already been done by MP startup code if (!HalpLowStubPhysicalAddress) { HalpLowStubPhysicalAddress = (PVOID)HalpAllocPhysicalMemory (LoaderBlock, LOW_MEMORY, 1, FALSE); if (HalpLowStubPhysicalAddress) { HalpLowStub = HalpMapPhysicalMemory(HalpLowStubPhysicalAddress, 1, MmCached); } } // // Claim a PTE that will be used for cache flushing in states S2 and S3. // HalpVirtAddrForFlush = HalpMapPhysicalMemory((PVOID)LOW_MEMORY, 1, MmCached); HalpPteForFlush = MiGetPteAddress(HalpVirtAddrForFlush); #endif return STATUS_SUCCESS; } VOID HaliAcpiTimerInit( // *** TBD should be ULONG_PTR IN ULONG TimerPort OPTIONAL, IN BOOLEAN TimerValExt ) /*++ Routine Description: This routine initializes the ACPI timer. Arguments: TimerPort - The address in I/O space of the ACPI timer. If this is 0, then the values from the cached FADT will be used. TimerValExt - signifies whether the timer is 24 or 32 bits. --*/ { #if defined(ACPI64) ULONG_PTR port = TimerPort; #else ULONG port = TimerPort; #endif BOOLEAN ext = TimerValExt; PAGED_CODE(); if (port == 0) { port = HalpFixedAcpiDescTable.x_pm_tmr_blk.Address.LowPart; if (HalpFixedAcpiDescTable.flags & TMR_VAL_EXT) { ext = TRUE; } else { ext = FALSE; } } HalaAcpiTimerInit(port, ext); } VOID HaliAcpiMachineStateInit( IN PPROCESSOR_INIT ProcInit, IN PHAL_SLEEP_VAL SleepValues, OUT PULONG PicVal ) /*++ Routine Description: This function is a callback used by the ACPI driver to notify the HAL with the processor blocks. Arguments: --*/ { POWER_STATE_HANDLER powerState; SLEEP_STATE_CONTEXT sleepContext; NTSTATUS status; PSYSTEM_POWER_STATE_DISABLE_REASON pReasonNoOSPM = NULL; SYSTEM_POWER_LOGGING_ENTRY PowerLoggingEntry; PAGED_CODE(); UNREFERENCED_PARAMETER(ProcInit); *PicVal = 1; // We only support APIC on IA64 RtlZeroMemory (&sleepContext, sizeof (sleepContext)); powerState.Context = NULL; pReasonNoOSPM = ExAllocatePoolWithTag( PagedPool, sizeof(SYSTEM_POWER_STATE_DISABLE_REASON), HAL_POOL_TAG ); if (pReasonNoOSPM) { RtlZeroMemory(pReasonNoOSPM, sizeof(SYSTEM_POWER_STATE_DISABLE_REASON)); pReasonNoOSPM->PowerReasonCode = SPSD_REASON_NONE; } // // Set up fake handlers that do nothing so testing device power // transitions isn't blocked. Only if hack flag is set, though // HalpReadRegistryAndApplyHacks (); if (HalpHackFlags & HalHackAddFakeSleepHandlersS1) { powerState.Type = PowerStateSleeping1; powerState.RtcWake = TRUE; powerState.Handler = &HaliAcpiFakeSleep; status = ZwPowerInformation(SystemPowerStateHandler, &powerState, sizeof(POWER_STATE_HANDLER), NULL, 0); } else { if (pReasonNoOSPM) { pReasonNoOSPM->PowerReasonCode = SPSD_REASON_NOOSPM; pReasonNoOSPM->AffectedState[PowerStateSleeping1] = TRUE; } } if (HalpHackFlags & HalHackAddFakeSleepHandlersS2) { powerState.Type = PowerStateSleeping2; powerState.RtcWake = TRUE; powerState.Handler = &HaliAcpiFakeSleep; status = ZwPowerInformation(SystemPowerStateHandler, &powerState, sizeof(POWER_STATE_HANDLER), NULL, 0); } else { if (pReasonNoOSPM) { pReasonNoOSPM->PowerReasonCode = SPSD_REASON_NOOSPM; pReasonNoOSPM->AffectedState[PowerStateSleeping2] = TRUE; } } if (HalpHackFlags & HalHackAddFakeSleepHandlersS3) { powerState.Type = PowerStateSleeping3; powerState.RtcWake = TRUE; powerState.Handler = &HaliAcpiFakeSleep; powerState.Context = ULongToPtr(sleepContext.AsULONG); status = ZwPowerInformation(SystemPowerStateHandler, &powerState, sizeof(POWER_STATE_HANDLER), NULL, 0); } else { if (pReasonNoOSPM) { pReasonNoOSPM->PowerReasonCode = SPSD_REASON_NOOSPM; pReasonNoOSPM->AffectedState[PowerStateSleeping3] = TRUE; } } // // we do not register support for hibernate // if (pReasonNoOSPM) { pReasonNoOSPM->PowerReasonCode = SPSD_REASON_NOOSPM; pReasonNoOSPM->AffectedState[PowerStateSleeping4] = TRUE; } if (pReasonNoOSPM && pReasonNoOSPM->PowerReasonCode != SPSD_REASON_NONE) { PowerLoggingEntry.LoggingType = LOGGING_TYPE_SPSD; PowerLoggingEntry.LoggingEntry = pReasonNoOSPM; ZwPowerInformation( SystemPowerLoggingEntry, &PowerLoggingEntry, sizeof(PowerLoggingEntry), NULL, 0 ); } // // For now all we are going to do is register a shutdown handler // that will call shutdown-restart // if (SleepValues[4].Supported) { powerState.Type = PowerStateShutdownOff; powerState.RtcWake = FALSE; powerState.Handler = &HaliAcpiSleep; sleepContext.bits.Pm1aVal = SleepValues[4].Pm1aVal; sleepContext.bits.Pm1bVal = SleepValues[4].Pm1bVal; sleepContext.bits.Flags = SLEEP_STATE_OFF; HalpShutdownContext = sleepContext; powerState.Context = ULongToPtr(sleepContext.AsULONG); status = ZwPowerInformation(SystemPowerStateHandler, &powerState, sizeof(POWER_STATE_HANDLER), NULL, 0); ASSERT(NT_SUCCESS(status)); } } ULONG HaliAcpiQueryFlags( VOID ) /*++ Routine Description: This routine is temporary is used to report the presence of the boot.ini switch Arguments: None Return Value: TRUE, if switch present --*/ { return HalpAcpiFlags; } NTSTATUS HaliInitPowerManagement( IN PPM_DISPATCH_TABLE PmDriverDispatchTable, IN OUT PPM_DISPATCH_TABLE *PmHalDispatchTable ) /*++ Routine Description: This is called by the ACPI driver to start the PM code. Arguments: PmDriverDispatchTable - table of functions provided by the ACPI driver for the HAL PmHalDispatchTable - table of functions provided by the HAL for the ACPI driver Return Value: status --*/ { OBJECT_ATTRIBUTES objAttributes; PCALLBACK_OBJECT callback; PHYSICAL_ADDRESS pAddr; UNICODE_STRING callbackName; NTSTATUS status; PFACS facs; PAGED_CODE(); // // Keep a pointer to the driver's dispatch table. // // ASSERT(PmDriverDispatchTable); // ASSERT(PmDriverDispatchTable->Signature == ACPI_HAL_DISPATCH_SIGNATURE); PmAcpiDispatchTable = PmDriverDispatchTable; // // Fill in the function table // HalAcpiDispatchTable.Signature = HAL_ACPI_DISPATCH_SIGNATURE; HalAcpiDispatchTable.Version = HAL_ACPI_DISPATCH_VERSION; HalAcpiDispatchTable.HalpAcpiTimerInit = &HaliAcpiTimerInit; HalAcpiDispatchTable.HalpAcpiTimerInterrupt = (pHalAcpiTimerInterrupt)&HalAcpiTimerCarry; HalAcpiDispatchTable.HalpAcpiMachineStateInit = &HaliAcpiMachineStateInit; HalAcpiDispatchTable.HalpAcpiQueryFlags = &HaliAcpiQueryFlags; HalAcpiDispatchTable.HalxPicStateIntact = &HalpAcpiPicStateIntact; HalAcpiDispatchTable.HalxRestorePicState = &HalpRestoreInterruptControllerState; HalAcpiDispatchTable.HalpSetVectorState = &HaliSetVectorState; HalAcpiDispatchTable.HalpPciInterfaceReadConfig = &HaliPciInterfaceReadConfig; HalAcpiDispatchTable.HalpPciInterfaceWriteConfig = &HaliPciInterfaceWriteConfig; HalAcpiDispatchTable.HalpSetMaxLegacyPciBusNumber = &HalpSetMaxLegacyPciBusNumber; HalAcpiDispatchTable.HalpIsVectorValid = &HaliIsVectorValid; *PmHalDispatchTable = (PPM_DISPATCH_TABLE)&HalAcpiDispatchTable; // // Fill in Hal's private dispatch table // HalSetWakeEnable = HaliSetWakeEnable; HalSetWakeAlarm = HaliSetWakeAlarm; // // Register callback that tells us to make // anything we need for sleeping non-pageable. // RtlInitUnicodeString(&callbackName, L"\\Callback\\PowerState"); InitializeObjectAttributes( &objAttributes, &callbackName, OBJ_CASE_INSENSITIVE | OBJ_PERMANENT, NULL, NULL ); ExCreateCallback(&callback, &objAttributes, FALSE, TRUE); ExRegisterCallback(callback, (PCALLBACK_FUNCTION)&HalpPowerStateCallback, NULL); #if 0 // // Find the location of the firmware waking vector. // N.B. If any of this fails, then HalpWakeVector will be NULL // and we won't support S2 or S3. // if (HalpFixedAcpiDescTable.x_firmware_ctrl.Address.QuadPart) { facs = HalpMapPhysicalMemory(HalpFixedAcpiDescTable.x_firmware_ctrl.Address, ADDRESS_AND_SIZE_TO_SPAN_PAGES(HalpFixedAcpiDescTable.x_firmware_ctrl.Address.LowPart, sizeof(FACS)), MmCached); if (facs) { if (facs->Signature == FACS_SIGNATURE) { HalpWakeVector = &facs->x_FirmwareWakingVector; } } } #endif return STATUS_SUCCESS; } NTSTATUS HalpQueryAcpiResourceRequirements( IN PIO_RESOURCE_REQUIREMENTS_LIST *Requirements ) /*++ Routine Description: This routine is a temporary stub that tries to detect the presence of an ACPI controller within the system. This code is meant to be inserted within NT's root system enumerator. Arguents: Requirements - pointer to list of resources Return Value: STATUS_SUCCESS - If we found a device object STATUS_NO_SUCH_DEVICE - If we can't find info about the new PDO --*/ { NTSTATUS ntStatus; PIO_RESOURCE_REQUIREMENTS_LIST resourceList; ULONG resourceListSize; PAGED_CODE(); // // Now figure out the number of resource that we need // ntStatus = HalpAcpiDetectResourceListSize( &resourceListSize ); // // Convert this resourceListSize into the number of bytes that we // must allocate // resourceListSize = sizeof(IO_RESOURCE_REQUIREMENTS_LIST) + ( (resourceListSize - 1) * sizeof(IO_RESOURCE_DESCRIPTOR) ); // // Allocate the correct number of bytes of the Resource List // resourceList = ExAllocatePoolWithTag( PagedPool, resourceListSize, HAL_POOL_TAG ); // // This call must have succeeded or we cannot lay claim to ACPI // if (resourceList == NULL) { return STATUS_INSUFFICIENT_RESOURCES; } // // Set up the ListSize in the structure // RtlZeroMemory(resourceList, resourceListSize); resourceList->ListSize = resourceListSize; // // Build the ResourceList here // ntStatus = HalpBuildAcpiResourceList(resourceList); // // Did we build the list okay? // if (!NT_SUCCESS(ntStatus)) { // // Free memory and exit // ExFreePool(resourceList); return STATUS_NO_SUCH_DEVICE; } *Requirements = resourceList; return ntStatus; } NTSTATUS HalpBuildAcpiResourceList( OUT PIO_RESOURCE_REQUIREMENTS_LIST List ) /*++ Routine Description: This is the routine that builds the ResourceList given the FADT and an arbitrary number of ResourceDescriptors. We assume that the ResourceList has been properly allocated and sized Arguments: List - The list to fill in Return Value: STATUS_SUCCESS if okay STATUS_UNSUCCESSUL if not --*/ { PIO_RESOURCE_DESCRIPTOR partialResource; ULONG sciVector; ULONG count = 0; PAGED_CODE(); ASSERT( List != NULL ); // // Specify some default values (for now) to determine the Bus Type and // the bus number // List->AlternativeLists = 1; List->InterfaceType = Isa; List->BusNumber = 0; List->List[0].Version = 1; List->List[0].Revision = 1; // // Is there an interrupt resource required? // if (HalpFixedAcpiDescTable.sci_int_vector != 0) { List->List[0].Descriptors[count].Type = CmResourceTypeInterrupt; List->List[0].Descriptors[count].ShareDisposition = CmResourceShareShared; List->List[0].Descriptors[count].Flags = CM_RESOURCE_INTERRUPT_LEVEL_SENSITIVE; // // The latest ACPI 2.0 spec allows the use of GSIVs in sci_int_vector in // the FADT. If the vector is >= PIC_VECTORS then don't translate, // otherwise use the translation, if any, specified in the ISO entry in // the MADT. // sciVector = HalpFixedAcpiDescTable.sci_int_vector; if (sciVector < PIC_VECTORS) { sciVector = HalpPicVectorRedirect[sciVector]; } List->List[0].Descriptors[count].u.Interrupt.MinimumVector = sciVector; List->List[0].Descriptors[count].u.Interrupt.MaximumVector = sciVector; List->List[0].Count++; count++; } #if DECLARE_FADT_RESOURCES_AT_ROOT // // Is there an SMI CMD IO Port? // if (HalpFixedAcpiDescTable.smi_cmd_io_port != 0) { List->List[0].Descriptors[count].Type = CmResourceTypePort; List->List[0].Descriptors[count].ShareDisposition = CmResourceShareDeviceExclusive; List->List[0].Descriptors[count].Flags =CM_RESOURCE_PORT_IO; List->List[0].Descriptors[count].u.Port.MinimumAddress.LowPart = PtrToUlong(HalpFixedAcpiDescTable.smi_cmd_io_port); List->List[0].Descriptors[count].u.Port.MaximumAddress.LowPart = PtrToUlong(HalpFixedAcpiDescTable.smi_cmd_io_port); List->List[0].Descriptors[count].u.Port.Length = 1; List->List[0].Descriptors[count].u.Port.Alignment = 1; List->List[0].Count++; count++; } // // Is there an PM1A Event Block IO Port? // if (HalpFixedAcpiDescTable.pm1a_evt_blk_io_port != 0) { List->List[0].Descriptors[count].Type = CmResourceTypePort; List->List[0].Descriptors[count].ShareDisposition = CmResourceShareDeviceExclusive; List->List[0].Descriptors[count].Flags = CM_RESOURCE_PORT_IO; List->List[0].Descriptors[count].u.Port.MinimumAddress.LowPart = HalpFixedAcpiDescTable.pm1a_evt_blk_io_port; List->List[0].Descriptors[count].u.Port.MaximumAddress.LowPart = HalpFixedAcpiDescTable.pm1a_evt_blk_io_port + (ULONG) HalpFixedAcpiDescTable.pm1_evt_len - 1; List->List[0].Descriptors[count].u.Port.Length = (ULONG) HalpFixedAcpiDescTable.pm1_evt_len; List->List[0].Descriptors[count].u.Port.Alignment = 1; List->List[0].Count++; count++; } // // Is there a PM1B Event Block IO Port? // if (HalpFixedAcpiDescTable.pm1b_evt_blk_io_port != 0) { List->List[0].Descriptors[count].Type = CmResourceTypePort; List->List[0].Descriptors[count].ShareDisposition = CmResourceShareDeviceExclusive; List->List[0].Descriptors[count].Flags = CM_RESOURCE_PORT_IO; List->List[0].Descriptors[count].u.Port.MinimumAddress.LowPart = HalpFixedAcpiDescTable.pm1b_evt_blk_io_port; List->List[0].Descriptors[count].u.Port.MaximumAddress.LowPart = HalpFixedAcpiDescTable.pm1b_evt_blk_io_port + (ULONG) HalpFixedAcpiDescTable.pm1_evt_len - 1; List->List[0].Descriptors[count].u.Port.Length = (ULONG) HalpFixedAcpiDescTable.pm1_evt_len; List->List[0].Descriptors[count].u.Port.Alignment = 1; List->List[0].Count++; count++; } // // Is there a PM1A Control Block IO Port? // if (HalpFixedAcpiDescTable.pm1a_ctrl_blk_io_port != 0) { List->List[0].Descriptors[count].Type = CmResourceTypePort; List->List[0].Descriptors[count].ShareDisposition = CmResourceShareDeviceExclusive; List->List[0].Descriptors[count].Flags = CM_RESOURCE_PORT_IO; List->List[0].Descriptors[count].u.Port.MinimumAddress.LowPart = HalpFixedAcpiDescTable.pm1a_ctrl_blk_io_port; List->List[0].Descriptors[count].u.Port.MaximumAddress.LowPart = HalpFixedAcpiDescTable.pm1a_ctrl_blk_io_port + (ULONG) HalpFixedAcpiDescTable.pm1_ctrl_len - 1; List->List[0].Descriptors[count].u.Port.Length = (ULONG) HalpFixedAcpiDescTable.pm1_ctrl_len; List->List[0].Descriptors[count].u.Port.Alignment = 1; List->List[0].Count++; count++; } // // Is there a PM1B Control Block IO Port? // if (HalpFixedAcpiDescTable.pm1b_ctrl_blk_io_port != 0) { List->List[0].Descriptors[count].Type = CmResourceTypePort; List->List[0].Descriptors[count].ShareDisposition = CmResourceShareDeviceExclusive; List->List[0].Descriptors[count].Flags = CM_RESOURCE_PORT_IO; List->List[0].Descriptors[count].u.Port.MinimumAddress.LowPart = HalpFixedAcpiDescTable.pm1b_ctrl_blk_io_port; List->List[0].Descriptors[count].u.Port.MaximumAddress.LowPart = HalpFixedAcpiDescTable.pm1b_ctrl_blk_io_port + (ULONG) HalpFixedAcpiDescTable.pm1_ctrl_len - 1; List->List[0].Descriptors[count].u.Port.Length = (ULONG) HalpFixedAcpiDescTable.pm1_ctrl_len; List->List[0].Descriptors[count].u.Port.Alignment = 1; List->List[0].Count++; count++; } // // Is there a PM2 Control Block IO Port? // if (HalpFixedAcpiDescTable.pm2_ctrl_blk_io_port != 0) { List->List[0].Descriptors[count].Type = CmResourceTypePort; List->List[0].Descriptors[count].ShareDisposition = CmResourceShareDeviceExclusive; List->List[0].Descriptors[count].Flags = CM_RESOURCE_PORT_IO; List->List[0].Descriptors[count].u.Port.MinimumAddress.LowPart = HalpFixedAcpiDescTable.pm2_ctrl_blk_io_port; List->List[0].Descriptors[count].u.Port.MaximumAddress.LowPart = HalpFixedAcpiDescTable.pm2_ctrl_blk_io_port + (ULONG) HalpFixedAcpiDescTable.pm2_ctrl_len - 1; List->List[0].Descriptors[count].u.Port.Length = (ULONG) HalpFixedAcpiDescTable.pm2_ctrl_len; List->List[0].Descriptors[count].u.Port.Alignment = 1; List->List[0].Count++; count++; } // // Is there a PM Timer Block IO Port? // if (HalpFixedAcpiDescTable.pm_tmr_blk_io_port != 0) { List->List[0].Descriptors[count].Type = CmResourceTypePort; List->List[0].Descriptors[count].ShareDisposition = CmResourceShareDeviceExclusive; List->List[0].Descriptors[count].Flags = CM_RESOURCE_PORT_IO; List->List[0].Descriptors[count].u.Port.MinimumAddress.LowPart = HalpFixedAcpiDescTable.pm_tmr_blk_io_port; List->List[0].Descriptors[count].u.Port.MaximumAddress.LowPart = HalpFixedAcpiDescTable.pm_tmr_blk_io_port + (ULONG) HalpFixedAcpiDescTable.pm_tmr_len - 1; List->List[0].Descriptors[count].u.Port.Length = (ULONG) HalpFixedAcpiDescTable.pm_tmr_len; List->List[0].Descriptors[count].u.Port.Alignment = 1; List->List[0].Count++; count++; } // // Is there a GP0 Block IO Port? // if (HalpFixedAcpiDescTable.gp0_blk_io_port != 0) { List->List[0].Descriptors[count].Type = CmResourceTypePort; List->List[0].Descriptors[count].ShareDisposition = CmResourceShareDeviceExclusive; List->List[0].Descriptors[count].Flags = CM_RESOURCE_PORT_IO; List->List[0].Descriptors[count].u.Port.MinimumAddress.LowPart = HalpFixedAcpiDescTable.gp0_blk_io_port; List->List[0].Descriptors[count].u.Port.MaximumAddress.LowPart = HalpFixedAcpiDescTable.gp0_blk_io_port + (ULONG) HalpFixedAcpiDescTable.gp0_blk_len - 1; List->List[0].Descriptors[count].u.Port.Length = (ULONG) HalpFixedAcpiDescTable.gp0_blk_len; List->List[0].Descriptors[count].u.Port.Alignment = 1; List->List[0].Count++; count++; } // // Is there a GP1 Block IO port? // if (HalpFixedAcpiDescTable.gp1_blk_io_port != 0) { List->List[0].Descriptors[count].Type = CmResourceTypePort; List->List[0].Descriptors[count].ShareDisposition = CmResourceShareDeviceExclusive; List->List[0].Descriptors[count].Flags = CM_RESOURCE_PORT_IO; List->List[0].Descriptors[count].u.Port.MinimumAddress.LowPart = HalpFixedAcpiDescTable.gp1_blk_io_port; List->List[0].Descriptors[count].u.Port.MaximumAddress.LowPart = HalpFixedAcpiDescTable.gp1_blk_io_port + (ULONG) HalpFixedAcpiDescTable.gp1_blk_len - 1; List->List[0].Descriptors[count].u.Port.Length = (ULONG) HalpFixedAcpiDescTable.gp1_blk_len; List->List[0].Descriptors[count].u.Port.Alignment = 1; List->List[0].Count++; count++; } #endif // DECLARE_FADT_RESOURCES_AT_ROOT return STATUS_SUCCESS; } NTSTATUS HalpAcpiDetectResourceListSize( OUT PULONG ResourceListSize ) /*++ Routine Description: Given a pointer to an FADT, determine the number of CM_PARTIAL_RESOURCE_DESCRIPTORS that are required to describe all the resource mentioned in the FADT Arguments: ResourceListSize - Location to store the answer Return Value: STATUS_SUCCESS if everything went okay --*/ { PAGED_CODE(); // // First of all, assume that we need no resources // *ResourceListSize = 0; // // Is there an interrupt resource required? // if (HalpFixedAcpiDescTable.sci_int_vector != 0) { *ResourceListSize += 1; } #if DECLARE_FADT_RESOURCES_AT_ROOT // // Is there an SMI CMD IO Port? // if (HalpFixedAcpiDescTable.smi_cmd_io_port != 0) { *ResourceListSize += 1; } // // Is there an PM1A Event Block IO Port? // if (HalpFixedAcpiDescTable.pm1a_evt_blk_io_port != 0) { *ResourceListSize += 1; } // // Is there a PM1B Event Block IO Port? // if (HalpFixedAcpiDescTable.pm1b_evt_blk_io_port != 0) { *ResourceListSize += 1; } // // Is there a PM1A Control Block IO Port? // if (HalpFixedAcpiDescTable.pm1a_ctrl_blk_io_port != 0) { *ResourceListSize += 1; } // // Is there a PM1B Control Block IO Port? // if (HalpFixedAcpiDescTable.pm1b_ctrl_blk_io_port != 0) { *ResourceListSize += 1; } // // Is there a PM2 Control Block IO Port? // if (HalpFixedAcpiDescTable.pm2_ctrl_blk_io_port != 0) { *ResourceListSize += 1; } // // Is there a PM Timer Block IO Port? // if (HalpFixedAcpiDescTable.pm_tmr_blk_io_port != 0) { *ResourceListSize += 1; } // // Is there a GP0 Block IO Port? // if (HalpFixedAcpiDescTable.gp0_blk_io_port != 0) { *ResourceListSize += 1; } // // Is there a GP1 Block IO Port? // if (HalpFixedAcpiDescTable.gp1_blk_io_port != 0) { *ResourceListSize += 1; } #endif // DECALRE_FADT_RESOURCES_AT_ROOT return STATUS_SUCCESS; } /*++ Routine Description: Scans the registry for TestFlags and sets the global hackflag to whatever the registry value is, if it exists. Arguments: None Return Value: None --*/ VOID HalpReadRegistryAndApplyHacks ( VOID ) { OBJECT_ATTRIBUTES ObjectAttributes; UNICODE_STRING UnicodeString; HANDLE BaseHandle = NULL; NTSTATUS status; KEY_VALUE_PARTIAL_INFORMATION hackflags; ULONG resultlength = 0; HalpHackFlags = 0; RtlInitUnicodeString (&UnicodeString, L"\\REGISTRY\\MACHINE\\SYSTEM\\CURRENTCONTROLSET\\Control\\HAL"); InitializeObjectAttributes(&ObjectAttributes, &UnicodeString, OBJ_CASE_INSENSITIVE, NULL, (PSECURITY_DESCRIPTOR) NULL); status = ZwOpenKey (&BaseHandle, KEY_READ, &ObjectAttributes); if (!NT_SUCCESS (status)) { return; } RtlInitUnicodeString (&UnicodeString, L"TestFlags"); status = ZwQueryValueKey (BaseHandle, &UnicodeString, KeyValuePartialInformation, &hackflags, sizeof (hackflags), &resultlength); if (!NT_SUCCESS (status)) { return; } if (hackflags.Type != REG_DWORD || hackflags.DataLength != sizeof (ULONG)) { return; } HalpHackFlags = (ULONG) *hackflags.Data; } ULONG HalpReadGenAddr( IN PGEN_ADDR GenAddr ) { ULONG i, result = 0, bitWidth, mask = 0; // // Figure out how wide our target register is. // bitWidth = GenAddr->BitWidth + GenAddr->BitOffset; if (bitWidth > 16) { bitWidth = 32; } else if (bitWidth <= 8) { bitWidth = 8; } else { bitWidth = 16; } switch (GenAddr->AddressSpaceID) { case AcpiGenericSpaceIO: ASSERT(!(GenAddr->Address.LowPart & 0Xffff0000)); ASSERT(GenAddr->Address.HighPart == 0); switch (bitWidth) { case 8: result = READ_PORT_UCHAR((PUCHAR)(UINT_PTR)GenAddr->Address.LowPart); break; case 16: result = READ_PORT_USHORT((PUSHORT)(UINT_PTR)GenAddr->Address.LowPart); break; case 32: result = READ_PORT_ULONG((PULONG)(UINT_PTR)GenAddr->Address.LowPart); break; default: return 0; } break; case AcpiGenericSpaceMemory: // // This code path depends on the fact that the addresses // in these structures have already been converted to // virtual addresses. // switch (bitWidth) { case 8: result = READ_REGISTER_UCHAR((PUCHAR)GenAddr->Address.QuadPart); break; case 16: result = READ_REGISTER_USHORT((PUSHORT)GenAddr->Address.QuadPart); break; case 32: result = READ_REGISTER_ULONG((PULONG)GenAddr->Address.QuadPart); break; default: return 0; } break; default: return 0; } // // If the register is not actually byte-aligned, correct for // that. // if (result && (bitWidth != GenAddr->BitWidth)) { result >>= GenAddr->BitOffset; result &= ((0x1ul << GenAddr->BitWidth) - 1); } return result; } VOID HalpWriteGenAddr( IN PGEN_ADDR GenAddr, IN ULONG Value ) { ULONG i, result = 0, bitWidth, data, mask = 0; data = 0; // // Figure out how wide our target register is. // bitWidth = GenAddr->BitWidth + GenAddr->BitOffset; if (bitWidth > 16) { bitWidth = 32; } else if (bitWidth <= 8) { bitWidth = 8; } else { bitWidth = 16; } switch (GenAddr->AddressSpaceID) { case AcpiGenericSpaceIO: ASSERT(!(GenAddr->Address.LowPart & 0Xffff0000)); ASSERT(GenAddr->Address.HighPart == 0); switch (bitWidth) { case 8: ASSERT(!(Value & 0xffffff00)); if ((GenAddr->BitOffset != 0) || (GenAddr->BitWidth != bitWidth)) { data = READ_PORT_UCHAR((PUCHAR)(UINT_PTR)GenAddr->Address.LowPart); mask = (UCHAR)~0 >> (8 - GenAddr->BitWidth); mask = (UCHAR)~(mask << GenAddr->BitOffset); data &= mask; data |= (UCHAR)Value << GenAddr->BitOffset; } else { data = Value; } WRITE_PORT_UCHAR((PUCHAR)(UINT_PTR)GenAddr->Address.LowPart, (UCHAR)data); break; case 16: ASSERT(!(Value & 0xffff0000)); if ((GenAddr->BitOffset != 0) || (GenAddr->BitWidth != bitWidth)) { data = READ_PORT_USHORT((PUSHORT)(UINT_PTR)GenAddr->Address.LowPart); mask = (USHORT)~0 >> (16 - GenAddr->BitWidth); mask = (USHORT)~(mask << GenAddr->BitOffset); data &= mask; data |= (USHORT)Value << GenAddr->BitOffset; } else { data = Value; } WRITE_PORT_USHORT((PUSHORT)(UINT_PTR)GenAddr->Address.LowPart, (USHORT)data); break; case 32: if ((GenAddr->BitOffset != 0) || (GenAddr->BitWidth != bitWidth)) { data = READ_PORT_ULONG((PULONG)(UINT_PTR)GenAddr->Address.LowPart); mask = (ULONG)~0 >> (32 - GenAddr->BitWidth); mask = ~(mask << GenAddr->BitOffset); data &= mask; data |= Value << GenAddr->BitOffset; } else { data = Value; } WRITE_PORT_ULONG((PULONG)(UINT_PTR)GenAddr->Address.LowPart, data); break; default: return; } break; case AcpiGenericSpaceMemory: // // This code path depends on the fact that the addresses // in these structures have already been converted to // virtual addresses. // switch (bitWidth) { case 8: ASSERT(!(Value & 0xffffff00)); if ((GenAddr->BitOffset != 0) || (GenAddr->BitWidth != bitWidth)) { data = READ_REGISTER_UCHAR((PUCHAR)GenAddr->Address.QuadPart); mask = (UCHAR)~0 >> (8 - GenAddr->BitWidth); mask = (UCHAR)~(mask << GenAddr->BitOffset); data &= mask; data |= (UCHAR)Value << GenAddr->BitOffset; } else { data = Value; } WRITE_REGISTER_UCHAR((PUCHAR)GenAddr->Address.QuadPart, (UCHAR)data); break; case 16: ASSERT(!(Value & 0xffff0000)); if ((GenAddr->BitOffset != 0) || (GenAddr->BitWidth != bitWidth)) { data = READ_REGISTER_USHORT((PUSHORT)GenAddr->Address.QuadPart); mask = (USHORT)~0 >> (16 - GenAddr->BitWidth); mask = (USHORT)~(mask << GenAddr->BitOffset); data &= mask; data |= (USHORT)Value << GenAddr->BitOffset; } else { data = Value; } WRITE_REGISTER_USHORT((PUSHORT)GenAddr->Address.QuadPart, (USHORT)data); break; case 32: if ((GenAddr->BitOffset != 0) || (GenAddr->BitWidth != bitWidth)) { data = READ_REGISTER_ULONG((PULONG)GenAddr->Address.QuadPart); mask = (ULONG)~0 >> (32 - GenAddr->BitWidth); mask = ~(mask << GenAddr->BitOffset); data &= mask; data |= Value << GenAddr->BitOffset; } else { data = Value; } WRITE_REGISTER_ULONG((PULONG)GenAddr->Address.QuadPart, data); break; default: return; } break; default: return; } } NTSTATUS HalpGetPlatformProperties( OUT PULONG Properties ) /*++ Routine Description: This function retrieves the platform properties as specified in the ACPI-style IPPT table if present on this platform. The table itself would've been retrieved earlier. Arguments: Properties - Pointer to a ULONG that will be updated to reflect the platform property flags if present. Return Value: NTSTATUS - STATUS_SUCCESS indicates the table was present and the ULONG pointed to by Properties contains valid data. --*/ { ULONG properties = 0; NTSTATUS status = STATUS_UNSUCCESSFUL; if (HalpPlatformPropertiesTable) { // // map IPPT flag to HAL_PLATFORM flag. Note that these do not // necessarily have to match 1:1. // if (HalpPlatformPropertiesTable->Flags & IPPT_DISABLE_WRITE_COMBINING) { properties |= HAL_PLATFORM_DISABLE_WRITE_COMBINING; } if (HalpPlatformPropertiesTable->Flags & IPPT_DISABLE_PTCG_TB_FLUSH) { properties |= HAL_PLATFORM_DISABLE_PTCG; } if (HalpPlatformPropertiesTable->Flags & IPPT_DISABLE_UC_MAIN_MEMORY) { properties |= HAL_PLATFORM_DISABLE_UC_MAIN_MEMORY; } status = STATUS_SUCCESS; } if ( HalpPlatformPropertiesEfiFlags ) { properties |= HalpPlatformPropertiesEfiFlags; status = STATUS_SUCCESS; } if (NT_SUCCESS(status)) { *Properties = properties; } return( status ); } NTSTATUS HalpGetCrossPartitionIpiInterface( OUT HAL_CROSS_PARTITION_IPI_INTERFACE * IpiInterface ) /*++ Routine Description: This function fills in the HAL_CROSS_PARTITION_IPI_INTERFACE structure pointed to by the argument with the appropriate hal function pointers. Arguments: IpiInterface - Pointer to HAL_CROSS_PARTITION_IPI_INTERFACE structure. Return Value: NTSTATUS --*/ { PAGED_CODE(); IpiInterface->HalSendCrossPartitionIpi = HalpSendCrossPartitionIpi; IpiInterface->HalReserveCrossPartitionInterruptVector = HalpReserveCrossPartitionInterruptVector; return STATUS_SUCCESS; }