/*++ Copyright (c) 1999 Microsoft Corporation Module Name: vihal.h Abstract: This module contains the private declarations to verify hal usage & apis. Author: Jordan Tigani (jtigani) 12-Nov-1999 Revision History: 6-23-00: (jtigani) Moved from halverifier.c --*/ ///////////////////////////////////////////////////////////////////// //////////////////////////////////////////////// Hal verifier defines ///////////////////////////////////////////////////////////////////// // // Bugcheck codes -- the major code is HAL_VERIFIER_DETECTED_VIOLATION -- // the sub-code is the HV_* // #define HAL_VERIFIER_DETECTED_VIOLATION 0xE6 #define HV_MISCELLANEOUS_ERROR 0x00 #define HV_PERFORMANCE_COUNTER_DECREASED 0x01 #define HV_PERFORMANCE_COUNTER_SKIPPED 0x02 #define HV_FREED_TOO_MANY_COMMON_BUFFERS 0x03 #define HV_FREED_TOO_MANY_ADAPTER_CHANNELS 0x04 #define HV_FREED_TOO_MANY_MAP_REGISTERS 0x05 #define HV_FREED_TOO_MANY_SCATTER_GATHER_LISTS 0x06 #define HV_LEFTOVER_COMMON_BUFFERS 0x07 #define HV_LEFTOVER_ADAPTER_CHANNELS 0x08 #define HV_LEFTOVER_MAP_REGISTERS 0x09 #define HV_LEFTOVER_SCATTER_GATHER_LISTS 0x0A #define HV_TOO_MANY_ADAPTER_CHANNELS 0x0B #define HV_TOO_MANY_MAP_REGISTERS 0x0C #define HV_DID_NOT_FLUSH_ADAPTER_BUFFERS 0x0D #define HV_DMA_BUFFER_NOT_LOCKED 0x0E #define HV_BOUNDARY_OVERRUN 0x0F #define HV_CANNOT_FREE_MAP_REGISTERS 0x10 #define HV_DID_NOT_PUT_ADAPTER 0x11 #define HV_MDL_FLAGS_NOT_SET 0x12 #define HV_BAD_IRQL 0x13 #define HV_BAD_IRQL_JUST_WARN 0x14 #define HV_OUT_OF_MAP_REGISTERS 0x15 #define HV_FLUSH_EMPTY_BUFFERS 0x16 #define HV_MISMATCHED_MAP_FLUSH 0x17 #define HV_ADAPTER_ALREADY_RELEASED 0x18 #define HV_NULL_DMA_ADAPTER 0x19 #define HV_MAP_FLUSH_NO_TRANSFER 0x1A #define HV_ADDRESS_NOT_IN_MDL 0x1b #define HV_DATA_LOSS 0x1c #define HV_DOUBLE_MAP_REGISTER 0x1d #define HV_OBSOLETE_API 0x1e #define HV_BAD_MDL 0x1f #define HV_FLUSH_NOT_MAPPED 0x20 #define HV_MAP_ZERO_LENGTH_BUFFER 0x21 /// // Codes to decide what to do when we hit a driver problem. /// #define HVC_IGNORE 0x00 // Do nothing. #define HVC_WARN 0x02 // Print message # continue #define HVC_ASSERT 0x04 // Print message # break #define HVC_BUGCHECK 0x08 // Print message # bugcheck #define HVC_ONCE 0x10 // combined with another code, #define HAL_VERIFIER_POOL_TAG 'VlaH' // HalV backwards // // // This is how we can recognize our double buffers // #define MAP_REGISTER_FILL_CHAR 0x0E #define PADDING_FILL_CHAR 0x0F // // Since we hook the "MapRegisterBase" with a MapRegisterFile, we sign // the first four bytes so we can tell the difference between the HAL's // map register base and our map register file. // #define MRF_SIGNATURE 0xACEFD00D // // This is what we use if the hal has returned a NULL map register base so // that drivers don't assume that they don't have flush adapter buffers. // #define MRF_NULL_PLACEHOLDER (PVOID)(LONG_PTR)(LONG)0xDEADF00D // // This should devide evenly into 2^32 // #define MAX_COUNTERS 0x20 // // Flags to indicate where the buffer tagging shall happen // #define TAG_BUFFER_START 0x01 #define TAG_BUFFER_END 0x02 // // How many map registers we can double-buffer at once // using physical contiguous memory. // This must be an integral multiple of the number of bits in a ULONG // #define MAX_CONTIGUOUS_MAP_REGISTERS 0x20 // // Flags that describe a map register // #define MAP_REGISTER_WRITE 0x01 // the transfer is a write to device #define MAP_REGISTER_READ 0x02 // the transfer is a read from device #define MAP_REGISTER_RW_MASK (MAP_REGISTER_WRITE | MAP_REGISTER_READ) ///////////////////////////////////////////////////////////////////// //////////////////////// Safe multi-processor 64 bit reads and writes ///////////////////////////////////////////////////////////////////// #if defined (_X86_) // // Only save the time stamp counter on x86 machines // #define ViRdtsc ViRdtscX86 // // Structure to do a locked 64 bit write /compare without // a spinlock. // typedef struct _TIMER64 { ULONG TimeLow; ULONG TimeHigh1; ULONG TimeHigh2; ULONG Reserved; // for packing sake // } TIMER64, *PTIMER64; // // Since we can't do a 64 bit atomic operation // without a spinlock, we have to monkey around a bit // This method comes from the acpi timer code. // #define SAFE_READ_TIMER64(WriteLargeInteger, ReadTimer64) \ \ while (TRUE) { \ (WriteLargeInteger).HighPart = (ReadTimer64).TimeHigh2; \ (WriteLargeInteger).LowPart = (ReadTimer64).TimeLow; \ \ if ((ULONG)(WriteLargeInteger).HighPart == (ReadTimer64).TimeHigh1) \ break; \ \ _asm { rep nop }; \ } #define SAFE_WRITE_TIMER64(WriteTimer64, ReadLargeInteger) \ WriteTimer64.TimeHigh1 = (ReadLargeInteger).HighPart; \ WriteTimer64.TimeLow = (ReadLargeInteger).LowPart; \ WriteTimer64.TimeHigh2 = (ReadLargeInteger).HighPart; // defined (_X86_) // #else // ! defined (_X86_) // #if defined(_IA64_) #define ViRdtsc ViRdtscIA64 #else // !_IA64_ // // Only save the time stamp counter on x86 and ia64 machines // #define ViRdtsc ViRdtscNull #endif // !_IA64_ // // Alpha or IA64 can do atomic 64 bit read/writes. // typedef LARGE_INTEGER TIMER64; #define SAFE_READ_TIMER64(WriteLargeInteger, ReadTimer64) \ InterlockedExchangePointer( \ &((PVOID) (WriteLargeInteger).QuadPart ), \ (PVOID) (ReadTimer64).QuadPart \ ); #define SAFE_WRITE_TIMER64(WriteTimer64, ReadLargeInteger) \ InterlockedExchangePointer( \ &((PVOID) (WriteTimer64).QuadPart ), \ (PVOID) (ReadLargeInteger).QuadPart \ ); // ! defined (_X86_) // #endif ///////////////////////////////////////////////////////////////////// ///////////////////////////////////////// Hal verifier global externs ///////////////////////////////////////////////////////////////////// extern ULONG VfVerifyDma; extern LOGICAL VfVerifyPerformanceCounter; extern LOGICAL ViDoubleBufferDma; extern LOGICAL ViProtectBuffers; extern LOGICAL ViInjectDmaFailures; extern LOGICAL ViSuperDebug; extern LOGICAL ViSufficientlyBootedForPcControl; extern LOGICAL ViSufficientlyBootedForDmaFailure; extern ULONG ViMaxMapRegistersPerAdapter; extern ULONG ViAllocationsFailedDeliberately; extern LARGE_INTEGER ViRequiredTimeSinceBoot; extern CHAR ViDmaVerifierTag[]; extern BOOLEAN ViPenalties[]; extern struct _HAL_VERIFIER_LOCKED_LIST ViAdapterList; extern struct _VF_TIMER_INFORMATION * ViTimerInformation; extern struct _DMA_OPERATIONS ViDmaOperations; extern struct _DMA_OPERATIONS ViLegacyDmaOperations; ///////////////////////////////////////////////////////////////////// ////////////////////////////////// Hal verifier structure definitions ///////////////////////////////////////////////////////////////////// typedef struct _TIMER_TICK { ULONG Processor; ULONG Reserved; LARGE_INTEGER TimeStampCounter; LARGE_INTEGER PerformanceCounter; LARGE_INTEGER TimerTick; } TIMER_TICK, *PTIMER_TICK; typedef struct _VF_TIMER_INFORMATION { KDPC RefreshDpc; KTIMER RefreshTimer; TIMER64 LastPerformanceCounter; TIMER64 UpperBound; TIMER64 LastTickCount; TIMER64 LastKdStartTime; LARGE_INTEGER PerformanceFrequency; ULONG CountsPerTick; ULONG CurrentCounter; TIMER_TICK SavedTicks[MAX_COUNTERS]; } VF_TIMER_INFORMATION, *PVF_TIMER_INFORMATION; typedef struct _HAL_VERIFIER_LOCKED_LIST { LIST_ENTRY ListEntry; KSPIN_LOCK SpinLock; } HAL_VERIFIER_LOCKED_LIST, *PHAL_VERIFIER_LOCKED_LIST; typedef struct _HAL_VERIFIER_BUFFER { USHORT PrePadBytes; USHORT PostPadBytes; ULONG RealLength; ULONG AdvertisedLength; PVOID RealStartAddress; PVOID AdvertisedStartAddress; PHYSICAL_ADDRESS RealLogicalStartAddress; PVOID AllocatorAddress; LIST_ENTRY ListEntry; } HAL_VERIFIER_BUFFER, *PHAL_VERIFIER_BUFFER; typedef struct _MAP_REGISTER { PVOID MappedToSa; ULONG BytesMapped; ULONG Flags; PVOID MapRegisterStart; } MAP_REGISTER, *PMAP_REGISTER; typedef struct _MAP_REGISTER_FILE { ULONG Signature; LIST_ENTRY ListEntry; BOOLEAN ContiguousMap; BOOLEAN ScatterGather; ULONG NumberOfMapRegisters; ULONG NumberOfRegistersMapped; PVOID MapRegisterBaseFromHal; PMDL MapRegisterMdl; PVOID MapRegisterBuffer; KSPIN_LOCK AllocationLock; MAP_REGISTER MapRegisters[1]; // Rest of the map registers go here // } MAP_REGISTER_FILE, *PMAP_REGISTER_FILE; typedef struct _VF_WAIT_CONTEXT_BLOCK { PVOID RealContext; PVOID RealCallback; PMDL RealMdl; PVOID RealStartVa; ULONG RealLength; ULONG NumberOfMapRegisters; struct _ADAPTER_INFORMATION * AdapterInformation; PSCATTER_GATHER_LIST ScatterGatherList; LIST_ENTRY ListEntry; PMAP_REGISTER_FILE MapRegisterFile; } VF_WAIT_CONTEXT_BLOCK, *PVF_WAIT_CONTEXT_BLOCK; // // Store a list of the real dma operations used by an adapter ... // when the driver allocates the adapter, we're going to replace all of its // dma operations with ours // typedef struct _ADAPTER_INFORMATION { LIST_ENTRY ListEntry; PDMA_ADAPTER DmaAdapter; PDEVICE_OBJECT DeviceObject; BOOLEAN DeferredRemove; BOOLEAN UseContiguousBuffers; BOOLEAN UseDmaChannel; BOOLEAN Inactive; PVOID CallingAddress; PDMA_OPERATIONS RealDmaOperations; HAL_VERIFIER_LOCKED_LIST ScatterGatherLists; HAL_VERIFIER_LOCKED_LIST CommonBuffers; HAL_VERIFIER_LOCKED_LIST MapRegisterFiles; ULONG MaximumMapRegisters; ULONG AllocatedMapRegisters; LONG ActiveMapRegisters; ULONG AllocatedScatterGatherLists; LONG ActiveScatterGatherLists; ULONG AllocatedCommonBuffers; ULONG FreedCommonBuffers; ULONG AllocatedAdapterChannels; // Must be 1 or less ! // ULONG FreedAdapterChannels; ULONG MappedTransferWithoutFlushing; DEVICE_DESCRIPTION DeviceDescription; ULONG AdapterChannelMapRegisters; VF_WAIT_CONTEXT_BLOCK AdapterChannelContextBlock; PVOID *ContiguousBuffers; // array of contiguous 3-page buffers to be used for double-buffering ULONG SuccessfulContiguousAllocations; // how many times we allocated contiguous space ULONG FailedContiguousAllocations; // how many times we failed to allocate contiguous space KSPIN_LOCK AllocationLock; // lock for our allocator routines ULONG AllocationStorage[MAX_CONTIGUOUS_MAP_REGISTERS / (sizeof(ULONG) * 8)]; // bitmask for allocator routines RTL_BITMAP AllocationMap; ULONG ContiguousMapRegisters; // allocated among ContiguousBufers ULONG NonContiguousMapRegisters; // allocated from non-Paged Pool } ADAPTER_INFORMATION, *PADAPTER_INFORMATION; ///////////////////////////////////////////////////////////////////// ////////////////////////////////// Hal verifier function declarations ///////////////////////////////////////////////////////////////////// //========================== // Declare our dma apis here // if NO_LEGACY_DRIVERS *is* // enabled // ========================= #if defined(NO_LEGACY_DRIVERS) VOID VfPutDmaAdapter( struct _DMA_ADAPTER * DmaAdapter ); PVOID VfAllocateCommonBuffer( IN struct _DMA_ADAPTER * DmaAdapter, IN ULONG Length, OUT PPHYSICAL_ADDRESS LogicalAddress, IN BOOLEAN CacheEnabled ); VOID VfFreeCommonBuffer( IN struct _DMA_ADAPTER * DmaAdapter, IN ULONG Length, IN PHYSICAL_ADDRESS LogicalAddress, IN PVOID VirtualAddress, IN BOOLEAN CacheEnabled ); NTSTATUS VfAllocateAdapterChannel( IN struct _DMA_ADAPTER * DmaAdapter, IN PDEVICE_OBJECT DeviceObject, IN ULONG NumberOfMapRegisters, IN PDRIVER_CONTROL ExecutionRoutine, IN PVOID Context ); PHYSICAL_ADDRESS VfMapTransfer( IN struct _DMA_ADAPTER * DmaAdapter, IN PMDL Mdl, IN PVOID MapRegisterBase, IN PVOID CurrentVa, IN OUT PULONG Length, IN BOOLEAN WriteToDevice ); BOOLEAN VfFlushAdapterBuffers( IN struct _DMA_ADAPTER * DmaAdapter, IN PMDL Mdl, IN PVOID MapRegisterBase, IN PVOID CurrentVa, IN ULONG Length, IN BOOLEAN WriteToDevice ); VOID VfFreeAdapterChannel( IN struct _DMA_ADAPTER * DmaAdapter ); VOID VfFreeMapRegisters( IN struct _DMA_ADAPTER * DmaAdapter, PVOID MapRegisterBase, ULONG NumberOfMapRegisters ); ULONG VfGetDmaAlignment( IN struct _DMA_ADAPTER * DmaAdapter ); ULONG VfReadDmaCounter( IN struct _DMA_ADAPTER * DmaAdapter ); NTSTATUS VfGetScatterGatherList ( IN struct _DMA_ADAPTER * DmaAdapter, IN PDEVICE_OBJECT DeviceObject, IN PMDL Mdl, IN PVOID CurrentVa, IN ULONG Length, IN PVOID ExecutionRoutine, IN PVOID Context, IN BOOLEAN WriteToDevice ); VOID VfPutScatterGatherList( IN struct _DMA_ADAPTER * DmaAdapter, IN struct _SCATTER_GATHER_LIST * ScatterGather, IN BOOLEAN WriteToDevice ); #endif // ===================== // New verified dma apis // ===================== NTSTATUS VfCalculateScatterGatherListSize( IN PDMA_ADAPTER DmaAdapter, IN OPTIONAL PMDL Mdl, IN PVOID CurrentVa, IN ULONG Length, OUT PULONG ScatterGatherListSize, OUT OPTIONAL PULONG pNumberOfMapRegisters ); NTSTATUS VfBuildScatterGatherList( IN PDMA_ADAPTER DmaAdapter, IN PDEVICE_OBJECT DeviceObject, IN PMDL Mdl, IN PVOID CurrentVa, IN ULONG Length, IN PDRIVER_LIST_CONTROL ExecutionRoutine, IN PVOID Context, IN BOOLEAN WriteToDevice, IN PVOID ScatterGatherBuffer, IN ULONG ScatterGatherLength ); NTSTATUS VfBuildMdlFromScatterGatherList( IN PDMA_ADAPTER DmaAdapter, IN PSCATTER_GATHER_LIST ScatterGather, IN PMDL OriginalMdl, OUT PMDL *TargetMdl ); IO_ALLOCATION_ACTION VfAdapterCallback( IN PDEVICE_OBJECT DeviceObject, IN PIRP Irp, IN PVOID MapRegisterBase, IN PVOID Context ); VOID VfScatterGatherCallback( IN struct _DEVICE_OBJECT *DeviceObject, IN struct _IRP *Irp, IN struct _SCATTER_GATHER_LIST * ScatterGather, IN PVOID Context ); // ============================== // Hal verifier internal routines // ============================== PADAPTER_INFORMATION ViHookDmaAdapter( IN PDMA_ADAPTER DmaAdapter, IN PDEVICE_DESCRIPTION DeviceDescription, IN ULONG NumberOfMapRegisters ); VOID ViReleaseDmaAdapter( IN PADAPTER_INFORMATION AdapterInformation ); PADAPTER_INFORMATION ViGetAdapterInformation( IN PDMA_ADAPTER DmaAdapter ); PVOID ViGetRealDmaOperation( IN PDMA_ADAPTER DmaAdapter, IN ULONG AdapterInformationOffset ); LARGE_INTEGER ViRdtsc( VOID ); VOID VfInitializeTimerInformation( VOID ); VOID ViRefreshCallback( IN PKDPC Dpc, IN PVOID DeferredContext, IN PVOID SystemArgument1, IN PVOID SystemArgument2 ); LOGICAL VfInjectDmaFailure ( VOID ); // ================================================= // Hal verfier special routines to track allocations // ================================================= PVOID ViSpecialAllocateCommonBuffer( IN PALLOCATE_COMMON_BUFFER AllocateCommonBuffer, IN PADAPTER_INFORMATION AdapterInformation, IN PVOID CallingAddress, IN ULONG Length, IN OUT PPHYSICAL_ADDRESS LogicalAddress, IN LOGICAL CacheEnabled ); LOGICAL ViSpecialFreeCommonBuffer( IN PFREE_COMMON_BUFFER FreeCommonBuffer, IN PADAPTER_INFORMATION AdapterInformation, IN PVOID CommonBuffer, LOGICAL CacheEnabled ); // =================================================== // Hal verfier special routines to do double buffering // =================================================== PMAP_REGISTER_FILE ViAllocateMapRegisterFile( IN PADAPTER_INFORMATION AdapterInformation, IN ULONG NumberOfMapRegisters ); LOGICAL ViFreeMapRegisterFile( IN PADAPTER_INFORMATION AdapterInformation, IN PMAP_REGISTER_FILE MapRegisterFile ); ULONG ViMapDoubleBuffer( IN PMAP_REGISTER_FILE MapRegisterFile, IN OUT PMDL Mdl, IN OUT PVOID CurrentVa, IN ULONG Length, IN BOOLEAN WriteToDevice ); LOGICAL ViFlushDoubleBuffer( IN PMAP_REGISTER_FILE MapRegisterFile, IN PMDL Mdl, IN PVOID CurrentVa, IN ULONG Length, IN BOOLEAN WriteToDevice ); LOGICAL ViAllocateMapRegistersFromFile( IN PMAP_REGISTER_FILE MapRegisterFile, IN PVOID CurrentSa, IN ULONG Length, IN BOOLEAN WriteToDevice, OUT PULONG MapRegisterNumber ); LOGICAL ViFreeMapRegistersToFile( IN PMAP_REGISTER_FILE MapRegisterFile, IN PVOID CurrentSa, IN ULONG Length ); PMAP_REGISTER ViFindMappedRegisterInFile( IN PMAP_REGISTER_FILE MapRegisterFile, IN PVOID CurrentSa, OUT PULONG MapRegisterNumber OPTIONAL ); LOGICAL ViSwap(IN OUT PVOID * MapRegisterBase, IN OUT PMDL * Mdl, IN OUT PVOID * CurrentVa ); VOID ViCheckAdapterBuffers( IN PADAPTER_INFORMATION AdapterInformation ); VOID ViTagBuffer( IN PVOID AdvertisedBuffer, IN ULONG AdvertisedLength, IN USHORT WhereToTag ); VOID ViCheckTag( IN PVOID AdvertisedBuffer, IN ULONG AdvertisedLength, IN BOOLEAN RemoveTag, IN USHORT WhereToCheck ); VOID ViInitializePadding( IN PVOID RealBufferStart, IN ULONG RealBufferLength, IN PVOID AdvertisedBufferStart, OPTIONAL IN ULONG AdvertisedBufferLength OPTIONAL ); VOID ViCheckPadding( IN PVOID RealBufferStart, IN ULONG RealBufferLength, IN PVOID AdvertisedBufferStart, OPTIONAL IN ULONG AdvertisedBufferLength OPTIONAL ); PULONG_PTR ViHasBufferBeenTouched( IN PVOID Address, IN ULONG_PTR Length, IN UCHAR ExpectedFillChar ); VOID VfAssert( IN LOGICAL Condition, IN ULONG Code, IN OUT PULONG Enable ); VOID ViMapTransferHelper( IN PMDL Mdl, IN PVOID CurrentVa, IN ULONG TransferLength, IN PULONG PageFrame, IN OUT PULONG Length ); VOID ViCommonBufferCalculatePadding( IN ULONG Length, OUT PULONG PrePadding, OUT PULONG PostPadding ); VOID ViAllocateContiguousMemory ( IN OUT PADAPTER_INFORMATION AdapterInformation ); PVOID ViAllocateFromContiguousMemory ( IN OUT PADAPTER_INFORMATION AdapterInformation, IN ULONG HintIndex ); LOGICAL ViFreeToContiguousMemory ( IN OUT PADAPTER_INFORMATION AdapterInformation, IN PVOID Address, IN ULONG HintIndex ); LOGICAL VfIsPCIBus ( IN PDEVICE_OBJECT PhysicalDeviceObject ); PDEVICE_OBJECT VfGetPDO ( IN PDEVICE_OBJECT DeviceObject ); ///////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////// Hal verifier macros ///////////////////////////////////////////////////////////////////// // // This is a kind of long macro but it lets us decide what to // do on certain kinds of errors. For instance, if we know // we are going to hit something once, we might set it to // HVC_WARN. Or if we know we will hit it 1000 times, but don't // want to take the code out completely (especially if we're doing // it on the fly), we can set it to HVC_IGNORE // #define VF_ASSERT(condition, code, message) \ { \ static ULONG enable = (ULONG) -1; \ if (enable == (ULONG) -1) \ enable = ViPenalties[code]; \ if (!(condition) && enable) \ { \ DbgPrint("* * * * * * * * HAL Verifier Detected Violation * * * * * * * *\n");\ DbgPrint("* *\n"); \ DbgPrint("* * VF: "); \ DbgPrint message; \ DbgPrint("\n"); \ DbgPrint("* *\n"); \ DbgPrint("* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *\n");\ \ VfAssert(condition, code, &enable); \ } \ } // // Old favorite: // // Control macro (used like a for loop) which iterates over all entries in // a standard doubly linked list. Head is the list head and the entries // are of type Type. A member called ListEntry is assumed to be the // LIST_ENTRY structure linking the entries together. Current contains a // pointer to each entry in turn. // #define FOR_ALL_IN_LIST(Type, Head, Current) \ for((Current) = CONTAINING_RECORD((Head)->Flink, Type, ListEntry); \ (Head) != &(Current)->ListEntry; \ (Current) = CONTAINING_RECORD((Current)->ListEntry.Flink, \ Type, \ ListEntry) \ ) #ifndef MIN #define MIN(a,b) ( ( (ULONG) (a)<(ULONG) (b))?(a):(b) ) #endif #define NOP #define VF_INITIALIZE_LOCKED_LIST(LockedList) \ KeInitializeSpinLock(&(LockedList)->SpinLock); \ InitializeListHead(&(LockedList)->ListEntry); #define VF_LOCK_LIST(ListToLock, OldIrql) \ KeAcquireSpinLock(&(ListToLock)->SpinLock, &OldIrql) #define VF_UNLOCK_LIST(ListToUnlock, OldIrql) \ KeReleaseSpinLock(&(ListToUnlock)->SpinLock, OldIrql) #define VF_IS_LOCKED_LIST_EMPTY(LockedList) \ IsListEmpty( &(LockedList)->ListEntry ) #define VF_ADD_TO_LOCKED_LIST(LockedList, AddMe) \ ExInterlockedInsertHeadList( \ &(LockedList)->ListEntry, \ &(AddMe)->ListEntry, \ &(LockedList)->SpinLock ) #define VF_REMOVE_FROM_LOCKED_LIST(LockedList, RemoveMe) \ { \ KIRQL OldIrql; \ VF_LOCK_LIST((LockedList), OldIrql); \ RemoveEntryList(&(RemoveMe)->ListEntry); \ VF_UNLOCK_LIST((LockedList), OldIrql); \ } #define VF_REMOVE_FROM_LOCKED_LIST_DONT_LOCK(LockedList, RemoveMe) \ RemoveEntryList(&(RemoveMe)->ListEntry); // // This is a bit of a hack so that reference counting for adapters will work. // If the device uses a dma channel, the HAL wants to keep it around. // There is a bit of funky logic that goes on to determine whether // a device uses an adapter channel so I've included it here, free of // charge. // #define VF_DOES_DEVICE_USE_DMA_CHANNEL(deviceDescription) \ ( \ ( (deviceDescription)->InterfaceType == Isa && \ (deviceDescription)->DmaChannel < 8 ) || \ ! (deviceDescription)->Master ) #define VF_DOES_DEVICE_REQUIRE_CONTIGUOUS_BUFFERS(deviceDescription) \ ( !(deviceDescription)->Master || ! (deviceDescription)->ScatterGather ) #define DMA_OFFSET(DmaOperationsField) \ FIELD_OFFSET(DMA_OPERATIONS, DmaOperationsField) #define DMA_INDEX(DmaOperations, Offset) \ (PVOID) \ *( (PVOID *) \ ( ( (PUCHAR) (DmaOperations) ) + \ (Offset) ) ) #define SIGN_MAP_REGISTER_FILE(MapRegisterFile) \ (MapRegisterFile)->Signature = MRF_SIGNATURE; #define VALIDATE_MAP_REGISTER_FILE_SIGNATURE(MapRegisterFile ) \ ((MapRegisterFile) && (MapRegisterFile)->Signature == MRF_SIGNATURE ) // // System dependent way to get the caller's address // #if defined(_X86_) #define GET_CALLING_ADDRESS(CallingAddress) \ { \ PVOID callersCaller; \ RtlGetCallersAddress(&CallingAddress, &callersCaller); \ } #else // ! defined(_X86_) // #define GET_CALLING_ADDRESS(CallingAddress) \ CallingAddress = (PVOID)_ReturnAddress(); #endif // ! defined(_X86_) // // From a map register file, map register number and the corresponding system address, // return the corresponding mapped address in system space. // #define MAP_REGISTER_SYSTEM_ADDRESS(MapRegisterFile, DriverCurrentSa, MapRegisterNumber) \ (PUCHAR) (MapRegisterFile)->MapRegisterBuffer + \ ( (MapRegisterNumber) << PAGE_SHIFT ) + \ BYTE_OFFSET(DriverCurrentSa) // // From a map register file, map register number and the corresponding system address, // return the corresponding mapped address as an index into the map register file's // MDL (i.e virtual address). // #define MAP_REGISTER_VIRTUAL_ADDRESS(MapRegisterFile, DriverCurrentSa, MapRegisterNumber) \ (PUCHAR) MmGetMdlVirtualAddress((MapRegisterFile)->MapRegisterMdl) + \ ( (MapRegisterNumber) << PAGE_SHIFT ) + \ BYTE_OFFSET(DriverCurrentSa) ///////////////////////////////////////////////////////////////////// //////////////////////////// Hal verifier inline function definitions ///////////////////////////////////////////////////////////////////// // // Since so many people don't raise the irql when they put the dma adapter, // just warn them. // __inline VOID VF_ASSERT_SPECIAL_IRQL(IN KIRQL Irql) { KIRQL currentIrql = KeGetCurrentIrql(); VF_ASSERT( currentIrql == Irql, HV_BAD_IRQL_JUST_WARN, ("**** Bad IRQL -- needed %x, got %x ****", (ULONG) Irql, (ULONG) currentIrql) ); } // VF_ASSERT_IRQL // __inline VOID VF_ASSERT_IRQL(IN KIRQL Irql) { KIRQL currentIrql = KeGetCurrentIrql(); VF_ASSERT( currentIrql == Irql, HV_BAD_IRQL, ("**** Bad IRQL -- needed %x, got %x ****", (ULONG) Irql, (ULONG) currentIrql) ); } // VF_ASSERT_IRQL // __inline VOID VF_ASSERT_MAX_IRQL(IN KIRQL MaxIrql) { KIRQL currentIrql = KeGetCurrentIrql(); VF_ASSERT( currentIrql <= MaxIrql, HV_BAD_IRQL, ("**** Bad IRQL -- needed %x or less, got %x ****", (ULONG) MaxIrql, (ULONG) currentIrql) ); } // ========================================= // Inlined functions to help with accounting // ========================================= __inline VOID ADD_MAP_REGISTERS( IN PADAPTER_INFORMATION AdapterInformation, IN ULONG NumberOfMapRegisters, IN BOOLEAN ScatterGather ) { ULONG activeMapRegisters = InterlockedExchangeAdd( &AdapterInformation->ActiveMapRegisters, NumberOfMapRegisters ) + NumberOfMapRegisters; InterlockedExchangeAdd((PLONG)(&AdapterInformation->AllocatedMapRegisters), NumberOfMapRegisters); VF_ASSERT( NumberOfMapRegisters <= AdapterInformation->MaximumMapRegisters, HV_TOO_MANY_MAP_REGISTERS, ( "Allocating too many map registers at a time: %x (max %x)", NumberOfMapRegisters, AdapterInformation->MaximumMapRegisters ) ); if (! ScatterGather ) { VF_ASSERT( activeMapRegisters <= AdapterInformation->MaximumMapRegisters, HV_OUT_OF_MAP_REGISTERS, ( "Allocated too many map registers : %x (max %x)", activeMapRegisters, AdapterInformation->MaximumMapRegisters ) ); } } // ADD_MAP_REGISTERS // __inline VOID SUBTRACT_MAP_REGISTERS( IN PADAPTER_INFORMATION AdapterInformation, IN ULONG NumberOfMapRegisters ) { LONG activeMapRegisters = InterlockedExchangeAdd( &AdapterInformation->ActiveMapRegisters, -((LONG) NumberOfMapRegisters) ) - NumberOfMapRegisters; VF_ASSERT( activeMapRegisters >= 0, HV_FREED_TOO_MANY_MAP_REGISTERS, ( "Freed too many map registers: %x", activeMapRegisters ) ); InterlockedExchange((PLONG)(&AdapterInformation->MappedTransferWithoutFlushing), 0); } // SUBTRACT_MAP_REGISTERS // __inline VOID INCREMENT_COMMON_BUFFERS( IN PADAPTER_INFORMATION AdapterInformation ) { InterlockedIncrement((PLONG)(&AdapterInformation->AllocatedCommonBuffers) ); } // INCREMENT_COMMON_BUFFERS // __inline VOID DECREMENT_COMMON_BUFFERS( IN PADAPTER_INFORMATION AdapterInformation ) { ULONG commonBuffersFreed = (ULONG) InterlockedIncrement( (PLONG)(&AdapterInformation->FreedCommonBuffers) ); VF_ASSERT( commonBuffersFreed <= AdapterInformation->AllocatedCommonBuffers, HV_FREED_TOO_MANY_COMMON_BUFFERS, ("Freed too many common buffers") ); } // DECREMENT_COMMON_BUFFERS // __inline VOID INCREASE_MAPPED_TRANSFER_BYTE_COUNT( IN PADAPTER_INFORMATION AdapterInformation, IN ULONG Length ) { ULONG mappedTransferCount; ULONG maxMappedTransfer; maxMappedTransfer = AdapterInformation->ActiveMapRegisters << PAGE_SHIFT; mappedTransferCount = InterlockedExchangeAdd( (PLONG)(&AdapterInformation->MappedTransferWithoutFlushing), (LONG) Length ) + Length; VF_ASSERT( mappedTransferCount <= maxMappedTransfer, HV_DID_NOT_FLUSH_ADAPTER_BUFFERS, ("Driver did not flush adapter buffers -- bytes mapped: %x (%x max)", mappedTransferCount, maxMappedTransfer )); } // INCREASE_MAPPED_TRANSFER_BYTE_COUNT // __inline VOID DECREASE_MAPPED_TRANSFER_BYTE_COUNT( IN PADAPTER_INFORMATION AdapterInformation, IN ULONG Length ) { UNREFERENCED_PARAMETER (Length); InterlockedExchange( (PLONG)(&AdapterInformation->MappedTransferWithoutFlushing), 0); } // DECREASE_MAPPED_TRANSFER_BYTE_COUNT // __inline VOID INCREMENT_ADAPTER_CHANNELS( IN PADAPTER_INFORMATION AdapterInformation ) { ULONG allocatedAdapterChannels = (ULONG) InterlockedIncrement( (PLONG)(&AdapterInformation->AllocatedAdapterChannels) ); VF_ASSERT( allocatedAdapterChannels == AdapterInformation->FreedAdapterChannels + 1, HV_TOO_MANY_ADAPTER_CHANNELS, ( "Driver has allocated too many simultaneous adapter channels" )); } // INCREMENT_ADAPTER_CHANNELS // __inline VOID DECREMENT_ADAPTER_CHANNELS( IN PADAPTER_INFORMATION AdapterInformation ) { ULONG adapterChannelsFreed = (ULONG) InterlockedIncrement( (PLONG)(&AdapterInformation->FreedAdapterChannels) ); VF_ASSERT( adapterChannelsFreed == AdapterInformation->AllocatedAdapterChannels, HV_FREED_TOO_MANY_ADAPTER_CHANNELS, ( "Driver has freed too many simultaneous adapter channels" )); } // DECREMENT_ADAPTER_CHANNELS // _inline VOID INCREMENT_SCATTER_GATHER_LISTS( IN PADAPTER_INFORMATION AdapterInformation ) { InterlockedIncrement( (PLONG)(&AdapterInformation->AllocatedScatterGatherLists) ); InterlockedIncrement( &AdapterInformation->ActiveScatterGatherLists); } // INCREMENT_SCATTER_GATHER_LISTS // __inline VOID DECREMENT_SCATTER_GATHER_LISTS ( IN PADAPTER_INFORMATION AdapterInformation ) { LONG activeScatterGatherLists = InterlockedDecrement( &AdapterInformation->ActiveScatterGatherLists ); VF_ASSERT( activeScatterGatherLists >= 0, HV_FREED_TOO_MANY_SCATTER_GATHER_LISTS, ( "Driver has freed too many scatter gather lists %x allocated, %x freed", AdapterInformation->AllocatedScatterGatherLists, AdapterInformation->AllocatedScatterGatherLists - activeScatterGatherLists) ); } // DECREMENT_SCATTER_GATHER_LISTS // __inline VOID VERIFY_BUFFER_LOCKED( IN PMDL Mdl ) { VF_ASSERT( MmAreMdlPagesLocked(Mdl), HV_DMA_BUFFER_NOT_LOCKED, ( "DMA Pages Not Locked! MDL %p for DMA not locked", Mdl) ); } // VERIFY_BUFFER_LOCKED // __inline PHAL_VERIFIER_BUFFER VF_FIND_BUFFER ( IN PHAL_VERIFIER_LOCKED_LIST LockedList, IN PVOID AdvertisedStartAddress ) { PHAL_VERIFIER_BUFFER verifierBuffer; KIRQL OldIrql; VF_LOCK_LIST(LockedList, OldIrql); FOR_ALL_IN_LIST(HAL_VERIFIER_BUFFER, &LockedList->ListEntry, verifierBuffer ) { if ((PUCHAR) verifierBuffer->RealStartAddress + verifierBuffer->PrePadBytes == AdvertisedStartAddress) { VF_UNLOCK_LIST(LockedList, OldIrql); return verifierBuffer; } } VF_UNLOCK_LIST(LockedList, OldIrql); return NULL; } // VF_FIND_BUFFER // __inline PADAPTER_INFORMATION VF_FIND_DEVICE_INFORMATION( IN PDEVICE_OBJECT DeviceObject ) { PADAPTER_INFORMATION adapterInformation; KIRQL OldIrql; VF_LOCK_LIST(&ViAdapterList, OldIrql); FOR_ALL_IN_LIST(ADAPTER_INFORMATION, &ViAdapterList.ListEntry, adapterInformation) { if (adapterInformation->DeviceObject == DeviceObject) { VF_UNLOCK_LIST(&ViAdapterList, OldIrql); return adapterInformation; } } VF_UNLOCK_LIST(&ViAdapterList, OldIrql); return NULL; } // VF_FIND_DEVICE_INFORMATION // __inline PADAPTER_INFORMATION VF_FIND_INACTIVE_ADAPTER( IN PDEVICE_OBJECT DeviceObject ) { PADAPTER_INFORMATION adapterInformation; KIRQL OldIrql; VF_LOCK_LIST(&ViAdapterList, OldIrql); FOR_ALL_IN_LIST(ADAPTER_INFORMATION, &ViAdapterList.ListEntry, adapterInformation) { if (adapterInformation->DeviceObject == DeviceObject && (adapterInformation->Inactive == TRUE || adapterInformation->DeferredRemove == TRUE)) { VF_UNLOCK_LIST(&ViAdapterList, OldIrql); return adapterInformation; } } VF_UNLOCK_LIST(&ViAdapterList, OldIrql); return NULL; } // VF_FIND_INACTIVE_ADAPTER // __inline VOID VF_MARK_FOR_DEFERRED_REMOVE( IN PDEVICE_OBJECT DeviceObject ) { PADAPTER_INFORMATION adapterInformation; KIRQL OldIrql; VF_LOCK_LIST(&ViAdapterList, OldIrql); FOR_ALL_IN_LIST(ADAPTER_INFORMATION, &ViAdapterList.ListEntry, adapterInformation) { if (adapterInformation->DeviceObject == DeviceObject) { adapterInformation->DeferredRemove = TRUE; } } VF_UNLOCK_LIST(&ViAdapterList, OldIrql); return ; } // VF_MARK_FOR_DEFERRED_REMOVE // __inline VOID VF_ASSERT_MAP_REGISTERS_CAN_BE_FREED( IN PADAPTER_INFORMATION AdapterInformation, IN PMAP_REGISTER_FILE MapRegisterFile ) { UNREFERENCED_PARAMETER (AdapterInformation); VF_ASSERT( MapRegisterFile->NumberOfRegistersMapped, HV_CANNOT_FREE_MAP_REGISTERS, ( "Cannot free map registers -- %x registers still mapped", MapRegisterFile->NumberOfMapRegisters) ); } // VF_ASSERT_MAP_REGISTERS_CAN_BE_FREED