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//-------------------------------------------------------------------------
// WINNT driver for PCIVME interface from ARW Elektronik, Germany ---------
// the ioctl functions
//
// (c) 1999-2004 ARW Elektronik
//
// this source code is published under GPL (Open Source). You can use, redistrubute and
// modify it unless this header is not modified or deleted. No warranty is given that
// this software will work like expected.
// This product is not authorized for use as critical component in life support systems
// wihout the express written approval of ARW Elektronik Germany.
//
// Please announce changes and hints to ARW Elektronik
//
// $Log: pcivme_io.c,v $
// Revision 1.3 2004/07/24 07:07:26 klaus
// Update copyright to 2004
//
// Revision 1.2 2003/11/15 19:12:51 klaus
// Update copyright to 2003
//
// Revision 1.1.1.1 2003/11/14 23:16:33 klaus
// First put into repository
//
// Revision 1.6 2002/10/27 18:30:57 klaus
// simpel typing correction
//
// Revision 1.5 2002/10/27 18:29:56 klaus
// honor backward compatibilty with non-extended modifier addressing
//
// Revision 1.4 2002/10/27 17:02:30 klaus
// File addressing bug > 2 Gbtye circumvent
//
// Revision 1.3 2002/10/27 16:17:48 klaus
// Typing bug fixed caused at log addition
//
// Revision 1.2 2002/10/27 16:11:02 klaus
// Added CVS log into header
//
// what who when
// started AR 03.07.1999
// first release 1.0 AR 17.10.1999
// changed resource allocation caused by WIN2000 AR 08.06.2002
//
//-------------------------------------------------------------------------
// INCLUDES
//
#include <ntddk.h>
#include <devioctl.h>
#include <pcivme_drv.h>
#include <pcivme.h>
#include <pcivme_v.h>
#include <pcivme_io.h>
#include <pciif.h>
#include <pcivme_i.h>
#include <pcivme_fifo.h>
//------------------------------------------------------------------------
// DEFINES
//
// buffers usage must match the corresponding ioctl code!
#define SET_BUFFERS_METHOD_OUT_DIRECT \
{\
InputLength = IrpStack->Parameters.DeviceIoControl.InputBufferLength;\
OutputLength = IrpStack->Parameters.DeviceIoControl.OutputBufferLength;\
pInputBuffer = ((void *)(Irp->AssociatedIrp.SystemBuffer));\
pOutputBuffer = ((void *)(MmGetSystemAddressForMdl(Irp->MdlAddress)));\
}
#define SET_BUFFERS_METHOD_IN_DIRECT \
{\
InputLength = IrpStack->Parameters.DeviceIoControl.InputBufferLength;\
OutputLength = IrpStack->Parameters.DeviceIoControl.OutputBufferLength;\
pInputBuffer = ((void *)(MmGetSystemAddressForMdl(Irp->MdlAddress)));\
pOutputBuffer = ((void *)(Irp->AssociatedIrp.SystemBuffer));\
}
#define SET_BUFFERS_METHOD_BUFFERED \
{\
InputLength = IrpStack->Parameters.DeviceIoControl.InputBufferLength;\
OutputLength = IrpStack->Parameters.DeviceIoControl.OutputBufferLength;\
pInputBuffer = pOutputBuffer = ((void *)(Irp->AssociatedIrp.SystemBuffer));\
}
#define COMPLETE_REQUEST \
{\
if (Status != STATUS_PENDING)\
{\
Irp->IoStatus.Status = Status; \
Irp->IoStatus.Information = irp_info; \
IoCompleteRequest(Irp,IO_NO_INCREMENT); \
}\
}
// compatibilty issues to WIN95 driver calls
#ifndef WORD
#define WORD USHORT
#endif
#ifndef DWORD
#define DWORD ULONG
#endif
#ifndef BYTE
#define BYTE UCHAR
#endif
#ifndef BOOL
#define BOOL BOOLEAN
#endif
#define MODIFIER_MASK 0x3F // mask for address modifier
//-------------------------------------------------------------------------
// GLOBALS
//
const PCIVME_INIT_ELEMENT init_element[] =
{{LCR, WORD_ACCESS, 0x4c, DISABLE_PCIADA_IRQS}, // disable interrupts
{LCR, WORD_ACCESS, 0x50, RELEASE_VMEMM}, // enable interface
{VIC, BYTE_ACCESS, (WORD)0x03, 0xf8+1}, // VIICR
{VIC, BYTE_ACCESS, (WORD)0x07, 0x78+1}, // VICR1
{VIC, BYTE_ACCESS, (WORD)0x0b, 0x78+2},
{VIC, BYTE_ACCESS, (WORD)0x0f, 0x78+3},
{VIC, BYTE_ACCESS, (WORD)0x13, 0x78+4},
{VIC, BYTE_ACCESS, (WORD)0x17, 0x78+5},
{VIC, BYTE_ACCESS, (WORD)0x1b, 0x78+6},
{VIC, BYTE_ACCESS, (WORD)0x1f, 0x78+7}, // VICR7
{VIC, BYTE_ACCESS, (WORD)0x23, 0xf8+0}, // DSICR
{VIC, BYTE_ACCESS, (WORD)0x27, 0xf8+1}, // LICR1
{VIC, BYTE_ACCESS, (WORD)0x2b, 0xf8+2},
{VIC, BYTE_ACCESS, (WORD)0x2f, 0xf8+3},
{VIC, BYTE_ACCESS, (WORD)0x33, 0xf8+4},
{VIC, BYTE_ACCESS, (WORD)0x37, 0xf8+5},
{VIC, BYTE_ACCESS, (WORD)0x3b, 0x38+6},
{VIC, BYTE_ACCESS, (WORD)0x3f, 0x38+7}, // LICR7
{VIC, BYTE_ACCESS, (WORD)0x43, 0xf8+2}, // ICGS
{VIC, BYTE_ACCESS, (WORD)0x47, 0xf8+3}, // ICMS
{VIC, BYTE_ACCESS, (WORD)0x4b, 0xf8+6}, // EGICR
{VIC, BYTE_ACCESS, (WORD)0x4f, 0x08}, // ICGS-IVBR (!)
{VIC, BYTE_ACCESS, (WORD)0x53, 0x0c}, // ICMS-IVBR (!)
{VIC, BYTE_ACCESS, (WORD)0x57, 0x00}, // LIVBR (!)
{VIC, BYTE_ACCESS, (WORD)0x5b, 0x10}, // EGIVBR (!)
{VIC, BYTE_ACCESS, (WORD)0x5f, 0x00}, // ICSR
{VIC, BYTE_ACCESS, (WORD)0x63, 0x00}, // ICR0
{VIC, BYTE_ACCESS, (WORD)0x67, 0x00},
{VIC, BYTE_ACCESS, (WORD)0x6b, 0x00},
{VIC, BYTE_ACCESS, (WORD)0x6f, 0x00},
{VIC, BYTE_ACCESS, (WORD)0x73, 0x00}, // ICR4
{VIC, BYTE_ACCESS, (WORD)0x83, 0xfe}, // VIRSR
{VIC, BYTE_ACCESS, (WORD)0x87, 0x0f}, // VIVR1
{VIC, BYTE_ACCESS, (WORD)0x8b, 0x0f},
{VIC, BYTE_ACCESS, (WORD)0x8f, 0x0f},
{VIC, BYTE_ACCESS, (WORD)0x93, 0x0f},
{VIC, BYTE_ACCESS, (WORD)0x97, 0x0f},
{VIC, BYTE_ACCESS, (WORD)0x9b, 0x0f},
{VIC, BYTE_ACCESS, (WORD)0x9f, 0x0f}, // VIVR7
{VIC, BYTE_ACCESS, (WORD)0xa3, 0x3c}, // TTR
{VIC, BYTE_ACCESS, (WORD)0xb3, 0x40}, // ARCR
{VIC, BYTE_ACCESS, (WORD)0xb7, 0x29}, // AMSR
{VIC, BYTE_ACCESS, (WORD)0xd3, 0x00}, // RCR
{IFR, LONG_ACCESS, (WORD)ADRHL, 0xF0F0F0F0}, // ADR-H, ADR-L
{IFR, WORD_ACCESS, (WORD)CSR , 0x0000}, // Contr-Reg
{VIC, BYTE_ACCESS, (WORD)0x7f, 0x80}, // ICR7
{LCR, WORD_ACCESS, 0x4c, DISABLE_PCIADA_IRQS},// disable interrupts
{STOP, WORD_ACCESS, 0, 0}};
const PCIVME_INIT_ELEMENT deinit_element_pre[] =
{{VIC, BYTE_ACCESS, (WORD)0x7f, 0x00}, // ICR7 - sysfail
{LCR, WORD_ACCESS, 0x4c, DISABLE_PCIADA_IRQS},// disable interrupts
{STOP, WORD_ACCESS, 0, 0}};
const PCIVME_INIT_ELEMENT deinit_element_post[] =
{{LCR, WORD_ACCESS, 0x50, INHIBIT_VMEMM}, // disable interface
{STOP, WORD_ACCESS, 0, 0}};
//--------------------------------------------------------------------------
// LOCAL FUNCTIONS
//
//--------------------------------------------------------------------------
// fast read or write functions - portable -
static void readByte(void *to, ULONG dwLength, void *from)
{
READ_REGISTER_BUFFER_UCHAR((PUCHAR)from, (PUCHAR)to, dwLength);
}
static void readWord(void *to, ULONG dwLength, void *from)
{
dwLength >>= 1;
READ_REGISTER_BUFFER_USHORT((PUSHORT)from, (PUSHORT)to, dwLength);
}
static void readLong(void *to, ULONG dwLength, void *from)
{
dwLength >>= 2;
READ_REGISTER_BUFFER_ULONG((PULONG)from, (PULONG)to, dwLength);
}
static void writeByte(void *to, ULONG dwLength, void *from)
{
WRITE_REGISTER_BUFFER_UCHAR((PUCHAR)to, (PUCHAR)from, dwLength);
}
static void writeWord(void *to, ULONG dwLength, void *from)
{
dwLength >>= 1;
WRITE_REGISTER_BUFFER_USHORT((PUSHORT)to, (PUSHORT)from, dwLength);
}
static void writeLong(void *to, ULONG dwLength, void *from)
{
dwLength >>= 2;
WRITE_REGISTER_BUFFER_ULONG((PULONG)to, (PULONG)from, dwLength);
}
//------------------------------------------------------------------------
// insert the irq queue into the linked list of queues
static NTSTATUS insertQueueInList(PFILE_OBJ pFile_obj, PCIADA *pciada)
{
NTSTATUS Status = STATUS_SUCCESS;
FIFO_LIST *next;
KIRQL OldIrql;
KdPrint(("insertQueueInList()\n"));
if (pFile_obj->bQueueIrq) // still enabled and in list
return Status;
// allocate memory to hold the list and its container
next = (FIFO_LIST *)ExAllocatePool(NonPagedPool, sizeof(FIFO_LIST));
if(next == (FIFO_LIST *)NULL)
return STATUS_INSUFFICIENT_RESOURCES;
else
{
// fill contents in entry
next->pFile_obj = pFile_obj;
next->pIrqListHandle = pFile_obj->pIrqListHandle;
// insert the entry in the list
KeAcquireSpinLock(&pciada->IrqListLock, &OldIrql);
KdPrint(("InsertHeadList(0x%08x, 0x%08x)\n", &pciada->IrqListList, &next->entry));
InsertHeadList(&pciada->IrqListList, &next->entry);
KeReleaseSpinLock(&pciada->IrqListLock, OldIrql);
// show and mark it
pFile_obj->bQueueIrq = TRUE;
}
return Status;
}
//------------------------------------------------------------------------
// remove the irq queue from the linked list of queues
NTSTATUS removeQueueFromList(PFILE_OBJ pFile_obj, PCIADA *pciada)
{
NTSTATUS Status = STATUS_SUCCESS;
FIFO_LIST *next;
PLIST_ENTRY pList;
KIRQL OldIrql;
KdPrint(("removeQueueFromList(0x%08x, 0x%08x)\n", pFile_obj, pciada));
pList = &pciada->IrqListList;
if ((pFile_obj == (FILE_OBJ *)NULL) || (pciada == (PCIADA *)NULL)) return Status;
// search for coincidence of pFile_obj in the list
KeAcquireSpinLock(&pciada->IrqListLock, &OldIrql);
while (pList->Flink != &pciada->IrqListList)
{
pList = pList->Flink;
next = CONTAINING_RECORD(pList, FIFO_LIST, entry);
if (next->pFile_obj == pFile_obj) // found
{
KdPrint(("RemoveEntryList(0%08x)\n", pList));
RemoveEntryList(pList);
ExFreePool((PVOID)next);
break;
}
}
KeReleaseSpinLock(&pciada->IrqListLock, OldIrql);
// in every case switch it off (again)
pFile_obj->bQueueIrq = FALSE;
KdPrint(("removeQueueFromList OK\n"));
return Status;
}
//--------------------------------------------------------------------------
// parsing of user supplied input for validy
static BOOLEAN check_command(const PCIVME_INIT_ELEMENT *psInitElement)
{
USHORT range;
USHORT access_size;
switch (psInitElement->range)
{
case LCR: range = 0x54; break;
case IFR: range = 0x0c; break;
case VIC: range = 0xe4;
if ((psInitElement->offset & 3) != 3)
return FALSE;
break;
default: range = 0; break;
}
switch (psInitElement->type)
{
case LONG_ACCESS: if (psInitElement->offset & 3)
return FALSE;
access_size = sizeof(ULONG);
break;
case WORD_ACCESS: if (psInitElement->offset & 1)
return FALSE;
access_size = sizeof( USHORT);
break;
case BYTE_ACCESS: access_size = sizeof( UCHAR); break;
default : access_size = 0xFFFF; break;
}
if ((psInitElement->offset + access_size) > range)
return FALSE; // ignore it
return TRUE;
}
//------------------------------------------------------------------------
// iterate through all commands
static VOID CmdMachine(const PCIVME_INIT_ELEMENT *psInitElement,
PVOID pvLcr, PVOID pvIfr)
{
PVOID adr;
// standard initialisierungen
while (psInitElement->range != STOP)
{
/*
KdPrint(("CmdMachine: %d %d 0x%02x 0x%02x\n",
psInitElement->range, psInitElement->type,
psInitElement->offset, psInitElement->value));
*/
if (check_command(psInitElement))
{
switch (psInitElement->range)
{
case LCR: adr = pvLcr; break;
case VIC: adr = (PVOID)((ULONG)pvIfr + (USHORT)VICBASE); break;
case IFR:
default: adr = pvIfr; break;
}
switch (psInitElement->type)
{
case LONG_ACCESS:
WRITE_REGISTER_ULONG((ULONG *)((UCHAR *)adr + psInitElement->offset),
psInitElement->value);
break;
case WORD_ACCESS:
WRITE_REGISTER_USHORT((USHORT *)((UCHAR *)adr + psInitElement->offset),
(USHORT)psInitElement->value);
break;
case BYTE_ACCESS:
default:
WRITE_REGISTER_UCHAR((UCHAR *)((UCHAR *)adr + psInitElement->offset),
(UCHAR)psInitElement->value);
break;
}
}
psInitElement++;
}
}
//------------------------------------------------------------------------
// init the interface with build in and user supplied constants
static BOOLEAN InitInterface(const PCIVME_INIT_COMMAND *psInitCmd,
PVOID pvLcr, PVOID pvIfr)
{
PCIVME_INIT_ELEMENT *psVie;
if ((psInitCmd == (PCIVME_INIT_COMMAND *)BOGUSADDRESS) ||
(psInitCmd == (PCIVME_INIT_COMMAND *)NULL) ||
(pvLcr == (PVOID)BOGUSADDRESS) ||
(pvLcr == (PVOID)NULL) ||
(pvIfr == (PVOID)BOGUSADDRESS) ||
(pvIfr == (PVOID)NULL))
return FALSE;
psVie = (PCIVME_INIT_ELEMENT *)psInitCmd->sVie;
CmdMachine(init_element , pvLcr, pvIfr); // standard initialisierungen
CmdMachine(psVie, pvLcr, pvIfr); // benutzer initialisierungen
return TRUE;
}
// deinit the interface with user supplied and build in constants
static BOOLEAN DeInitInterface(const PCIVME_INIT_COMMAND *psDeInitCmd,
PVOID pvLcr, PVOID pvIfr)
{
PCIVME_INIT_ELEMENT *psVie;
if ((psDeInitCmd == (PCIVME_INIT_COMMAND *)BOGUSADDRESS) ||
(psDeInitCmd == (PCIVME_INIT_COMMAND *)NULL) ||
(pvLcr == (PVOID)BOGUSADDRESS) ||
(pvLcr == (PVOID)NULL) ||
(pvIfr == (PVOID)BOGUSADDRESS) ||
(pvIfr == (PVOID)NULL))
return FALSE;
psVie = (PCIVME_INIT_ELEMENT *)psDeInitCmd->sVie;
CmdMachine(deinit_element_pre, pvLcr, pvIfr); // standard de-initialisierungen
CmdMachine(psVie, pvLcr, pvIfr); // benutzer de-initialisierungen
CmdMachine(deinit_element_post , pvLcr, pvIfr); // disable interface
return TRUE;
}
//------------------------------------------------------------------------
// a inserter into a user managed queue of IRPs
//
void InsertIRPtoQueue(PDEVICE_OBJECT device_Obj, PIRP Irp)
{
DEVICE_EXT *pDevExt = (DEVICE_EXT *)(device_Obj->DeviceExtension);
KIRQL oldIrql;
KdPrint(("InsertIRPtoQueue(0x%08x)\n", Irp));
KeAcquireSpinLock(&pDevExt->IRPLock, &oldIrql);
InsertHeadList(&pDevExt->IRPList, &Irp->Tail.Overlay.ListEntry);
KeReleaseSpinLock(&pDevExt->IRPLock, oldIrql);
}
//------------------------------------------------------------------------
// a remover out of a user managed queue of IRPs
//
PIRP RemoveIRPfromQueue(PDEVICE_OBJECT device_Obj, FILE_OBJ *pFile_obj)
{
DEVICE_EXT *pDevExt = (DEVICE_EXT *)(device_Obj->DeviceExtension);
KIRQL oldIrql;
register PLIST_ENTRY pList = &pDevExt->IRPList;
PIRP Irp;
PIRP pIrp = (PIRP)NULL;
FILE_OBJ *file_obj;
KdPrint(("RemoveIRPfromQueue()\n"));
KeAcquireSpinLock(&pDevExt->IRPLock, &oldIrql);
while (pList->Flink != &pDevExt->IRPList) // until the end is reached
{
pList = pList->Flink;
Irp = CONTAINING_RECORD(pList, IRP, Tail.Overlay.ListEntry);
file_obj = (FILE_OBJ *)Irp->Tail.Overlay.OriginalFileObject->FsContext;
KdPrint(("pList 0x%08x, pList->Flink 0x%08x, Irp 0x%08x, file_obj 0x%08x\n", pList, pList->Flink, Irp, file_obj));
if ((file_obj == pFile_obj) && (pFile_obj != (FILE_OBJ *)NULL))
{
RemoveEntryList(pList);
pIrp = Irp;
break;
}
}
KeReleaseSpinLock(&pDevExt->IRPLock, oldIrql);
KdPrint(("return RemoveIRPfromQueue(0x%08x)\n", pIrp));
return pIrp;
}
//------------------------------------------------------------------------
// a remover out of a user managed queue of IRPs
//
PIRP RemoveIRPfromQueueByIrp(PDEVICE_OBJECT device_Obj, PIRP pIrpIn)
{
DEVICE_EXT *pDevExt = (DEVICE_EXT *)(device_Obj->DeviceExtension);
KIRQL oldIrql;
register PLIST_ENTRY pList = &pDevExt->IRPList;
PIRP Irp;
PIRP pIrp = (PIRP)NULL;
KdPrint(("RemoveIRPfromQueueByIrp()\n"));
KeAcquireSpinLock(&pDevExt->IRPLock, &oldIrql);
while (pList->Flink != &pDevExt->IRPList) // until the end is reached
{
pList = pList->Flink;
Irp = CONTAINING_RECORD(pList, IRP, Tail.Overlay.ListEntry);
KdPrint(("pList 0x%08x, pList->Flink 0x%08x, Irp 0x%08x\n", pList, pList->Flink, Irp));
if (pIrpIn == Irp)
{
RemoveEntryList(pList);
pIrp = Irp;
break;
}
}
KeReleaseSpinLock(&pDevExt->IRPLock, oldIrql);
KdPrint(("return RemoveIRPfromQueueByIrp(0x%08x)\n", pIrp));
return pIrp;
}
//------------------------------------------------------------------------
// the default cancel routine for an queued Irp
//
void CancelRequest(PDEVICE_OBJECT device_Obj, PIRP Irp)
{
PIRP pIrpCancel = RemoveIRPfromQueueByIrp(device_Obj, Irp);
if (pIrpCancel == (PIRP)NULL)
{
IoReleaseCancelSpinLock(Irp->CancelIrql);
KdPrint(("Nothing to do: CancelRequest(0x%08x)\n", Irp));
return;
}
else
{
IoReleaseCancelSpinLock(Irp->CancelIrql);
KdPrint(("Done: CancelRequest(0x%08x)\n", Irp));
Irp->IoStatus.Status = STATUS_CANCELLED;
Irp->IoStatus.Information = 0;
IoCompleteRequest(Irp, IO_NO_INCREMENT);
}
}
//------------------------------------------------------------------------
// the custom deffered routine to finish blocking io on read_vector
void fMyDefferedRoutine(PKDPC Dpc, PVOID pvDevice_object,
PVOID pvPciada, PVOID pvVector)
{
NTSTATUS Status = STATUS_SUCCESS;
ULONG irp_info = sizeof(PCIVME_VECTOR_RESPONSE);
PIRP Irp = (PIRP)NULL;
PDEVICE_OBJECT device_Obj = (PDEVICE_OBJECT)pvDevice_object;
PCIADA *pciada = (PCIADA *)pvPciada;
FIFO_LIST *next;
KIRQL oldIrqlCancel;
KIRQL oldIrqlList;
register PLIST_ENTRY pList = &pciada->IrqListList;
UNREFERENCED_PARAMETER(pvVector);
UNREFERENCED_PARAMETER(Dpc);
KdPrint(("fMyDefferedRoutine()\n"));
// beware off damage due to intercept with cancel of thread
IoAcquireCancelSpinLock(&oldIrqlCancel);
KeAcquireSpinLock(&pciada->IrqListLock, &oldIrqlList);
while (pList->Flink != &pciada->IrqListList) // until the end is reached
{
pList = pList->Flink;
KeReleaseSpinLock(&pciada->IrqListLock, oldIrqlList); // shorten block
next = CONTAINING_RECORD(pList, FIFO_LIST, entry);
// get my associated packet
Irp = RemoveIRPfromQueue(device_Obj, next->pFile_obj);
if (Irp != (PIRP)NULL)
{
PCIVME_VECTOR_REQUEST *pVectorRequest = (PCIVME_VECTOR_REQUEST *)(Irp->AssociatedIrp.SystemBuffer);
PCIVME_VECTOR_RESPONSE *pVectorResponse = (PCIVME_VECTOR_RESPONSE *)pVectorRequest;
USHORT wRequestCount = pVectorRequest->wRequestCount;
UCHAR *pbVector = &pVectorResponse->bStatusID;
FILE_OBJ *file_obj = (FILE_OBJ *)Irp->Tail.Overlay.OriginalFileObject->FsContext;
UCHAR bNumberOfElements = (UCHAR) NumberOfElements(file_obj->pIrqListHandle);
// pull the vectors off the fifo
pVectorResponse->wCount = 0;
while ((bNumberOfElements) && (wRequestCount--))
{
bNumberOfElements = (UCHAR) PullElement(file_obj->pIrqListHandle,
(void *)pbVector);
pbVector++;
pVectorResponse->wCount++;
}
pVectorResponse->wPendingCount = bNumberOfElements;
pVectorResponse->bOverflow = CheckAndClearOverflow(file_obj->pIrqListHandle);
irp_info = sizeof(PCIVME_VECTOR_RESPONSE) +
sizeof(UCHAR) * (pVectorResponse->wCount - 1);
// release the cancel routine from this Irp
IoSetCancelRoutine(Irp, NULL);
COMPLETE_REQUEST;
}
KeAcquireSpinLock(&pciada->IrqListLock, &oldIrqlList);
}
// release the spin locks
KeReleaseSpinLock(&pciada->IrqListLock, oldIrqlList);
IoReleaseCancelSpinLock(oldIrqlCancel);
}
//------------------------------------------------------------------------
// all functions called from ioctl jump table
//
//------------------------------------------------------------------------
// initialize all hardware associated to a given wModuleNumber
static NTSTATUS ioctl_init_hardware(PDEVICE_OBJECT device_Obj, PIRP Irp, PIO_STACK_LOCATION IrpStack)
{
NTSTATUS Status = STATUS_SUCCESS;
ULONG irp_info = 0;
PVOID pInputBuffer,pOutputBuffer;
ULONG InputLength, OutputLength;
DEVICE_EXT *pDevExt;
PCIVME_INIT_COMMAND *pInitCommand;
PCIADA *pciada;
FILE_OBJ *file_obj = (FILE_OBJ *)Irp->Tail.Overlay.OriginalFileObject->FsContext;
pDevExt = (DEVICE_EXT *)(device_Obj->DeviceExtension);
SET_BUFFERS_METHOD_BUFFERED;
// do what must be here in between --- start ---
pInitCommand = (PCIVME_INIT_COMMAND *)pInputBuffer;
KdPrint(("ioctl_init_hardware(%d)\n", file_obj->uwAssociatedVMEMM));
pciada = pDevExt->vmemm[file_obj->uwAssociatedVMEMM];
if (pciada != NULL)
{
KIRQL oldIrql;
if (pciada->dwLinkCount == 1)
{
// lock other users out
KeAcquireSpinLock(&pciada->AccessLock, &oldIrql);
if (InitInterface(pInitCommand, pciada->pvVirtLcr, pciada->pvVirtIfr))
{
// fill cache for page and modifier
pciada->dwVMEPage = READ_REGISTER_ULONG(pciada->pdwVMEAdr) & ~VME_ADR_MASK;
pciada->bModifier = READ_REGISTER_UCHAR(pciada->pbModifier) & MODIFIER_MASK;
}
else
Status = STATUS_UNSUCCESSFUL;
// release the lock
KeReleaseSpinLock(&pciada->AccessLock, oldIrql);
}
else
Status = STATUS_UNSUCCESSFUL;
}
else
Status = STATUS_UNSUCCESSFUL;
// do what must be here in between --- end ---
COMPLETE_REQUEST;
KdPrint(("ioctl_init_hardware(), Status = 0x%08x\n", Status));
return Status;
}
//------------------------------------------------------------------------
// De-initialise all hardware associated to a given wModuleNumber
static NTSTATUS ioctl_deinit_hardware(PDEVICE_OBJECT device_Obj, PIRP Irp, PIO_STACK_LOCATION IrpStack)
{
NTSTATUS Status = STATUS_SUCCESS;
ULONG irp_info = 0;
PVOID pInputBuffer,pOutputBuffer;
ULONG InputLength, OutputLength;
DEVICE_EXT *pDevExt;
PCIVME_INIT_COMMAND *pInitCommand;
PCIADA *pciada;
FILE_OBJ *file_obj = (FILE_OBJ *)Irp->Tail.Overlay.OriginalFileObject->FsContext;
KdPrint(("ioctl_deinit_hardware()\n"));
pDevExt = (DEVICE_EXT *)(device_Obj->DeviceExtension);
SET_BUFFERS_METHOD_BUFFERED;
// do what must be hier in between --- start ---
pInitCommand = (PCIVME_INIT_COMMAND *)pInputBuffer;
KdPrint(("ioctl_deinit_hardware(%d)\n", file_obj->uwAssociatedVMEMM));
pciada = pDevExt->vmemm[file_obj->uwAssociatedVMEMM];
if (pciada != NULL)
{
KIRQL oldIrql;
if (pciada->dwLinkCount == 1)
{
// lock other users out
KeAcquireSpinLock(&pciada->AccessLock, &oldIrql);
if (DeInitInterface(pInitCommand, pciada->pvVirtLcr, pciada->pvVirtIfr))
globalInterruptDisable(pciada);
else
Status = STATUS_UNSUCCESSFUL;
// everyone likes to have PCIVME
KeReleaseSpinLock(&pciada->AccessLock, oldIrql);
}
else
Status = STATUS_UNSUCCESSFUL;
}
else
Status = STATUS_UNSUCCESSFUL;
// do what must be hier in between --- end ---
COMPLETE_REQUEST;
KdPrint(("ioctl_deinit_hardware(), Status = 0x%08x\n", Status));
return Status;
}
//------------------------------------------------------------------------
// a dummy entry because of compatibiltiy (near) WIN95 driver
static NTSTATUS ioctl_dummy(PDEVICE_OBJECT device_Obj, PIRP Irp, PIO_STACK_LOCATION IrpStack)
{
NTSTATUS Status = STATUS_SUCCESS;
ULONG irp_info = 0;
PVOID pInputBuffer,pOutputBuffer;
ULONG InputLength, OutputLength;
PCIVME_INIT_COMMAND *pInitCommand;
FILE_OBJ *file_obj = (FILE_OBJ *)Irp->Tail.Overlay.OriginalFileObject->FsContext;
SET_BUFFERS_METHOD_BUFFERED;
UNREFERENCED_PARAMETER(device_Obj);
#ifndef _DEBUG
UNREFERENCED_PARAMETER(file_obj);
#endif
pInitCommand = (PCIVME_INIT_COMMAND *)pInputBuffer;
KdPrint(("ioctl_dummy(%d)\n", file_obj->uwAssociatedVMEMM));
// do what must be here in between -----------
// do what must be here in between --- end ---
COMPLETE_REQUEST;
KdPrint(("ioctl_dummy(), Status = 0x%08x\n", Status));
return Status;
}
//------------------------------------------------------------------------
// requests fixed unchangeable information - not compatible to WIN95 driver
static NTSTATUS ioctl_get_static_status(PDEVICE_OBJECT device_Obj, PIRP Irp, PIO_STACK_LOCATION IrpStack)
{
NTSTATUS Status = STATUS_SUCCESS;
ULONG irp_info = sizeof(PCIVME_STATIC_STATUS);
PVOID pInputBuffer,pOutputBuffer;
ULONG InputLength, OutputLength;
PCIADA *pciada;
DEVICE_EXT *pDevExt;
PCIVME_STATIC_STATUS *pStaticStatus;
FILE_OBJ *file_obj = (FILE_OBJ *)Irp->Tail.Overlay.OriginalFileObject->FsContext;
pDevExt = (DEVICE_EXT *)(device_Obj->DeviceExtension);
SET_BUFFERS_METHOD_BUFFERED;
KdPrint(("ioctl_get_static_status(%d)\n", file_obj->uwAssociatedVMEMM));
// do what must be here in between -----------
if (OutputLength >= sizeof(PCIVME_STATIC_STATUS))
{
pStaticStatus = (PCIVME_STATIC_STATUS *)pOutputBuffer;
pciada = pDevExt->vmemm[file_obj->uwAssociatedVMEMM];
pStaticStatus->dwInterface = file_obj->uwAssociatedVMEMM;
pStaticStatus->wNumMemWindows = 3;
pStaticStatus->wNumIOPorts = 2;
pStaticStatus->wNumIRQs = 1;
pStaticStatus->wNumDMAs = 0;
pStaticStatus->dwLinkCount = pciada->dwLinkCount;
pStaticStatus->wModuleType = pciada->wModuleType;
pStaticStatus->wFPGAVersion = pciada->wFPGAVersion;
pStaticStatus->wModuleNumber = pciada->wModuleNumber;
pStaticStatus->wWordMode = pciada->bWordMode;
pStaticStatus->wSysControl = pciada->bSysControl;
pStaticStatus->wConnected = pciada->bConnected;
pStaticStatus->pvLcr = pciada->pvPhysLcr;
pStaticStatus->pvIfr = pciada->pvPhysIfr;
pStaticStatus->dwDriverVersion = DRIVER_VERSION;
pStaticStatus->dwDriverVariant = DRIVER_VARIANT;
}
else
Status = STATUS_BUFFER_TOO_SMALL;
// do what must be here in between --- end ---
COMPLETE_REQUEST;
KdPrint(("ioctl_get_static_status(), Status = 0x%08x\n", Status));
return Status;
}
//------------------------------------------------------------------------
// requests changeable status
static NTSTATUS ioctl_get_dynamic_status(PDEVICE_OBJECT device_Obj, PIRP Irp, PIO_STACK_LOCATION IrpStack)
{
NTSTATUS Status = STATUS_SUCCESS;
ULONG irp_info = sizeof(PCIVME_DYNAMIC_STATUS);
PVOID pInputBuffer,pOutputBuffer;
ULONG InputLength, OutputLength;
PCIADA *pciada;
DEVICE_EXT *pDevExt;
PCIVME_DYNAMIC_STATUS *pDynamicStatus;
FILE_OBJ *file_obj = (FILE_OBJ *)Irp->Tail.Overlay.OriginalFileObject->FsContext;
SET_BUFFERS_METHOD_BUFFERED;
KdPrint(("ioctl_get_dynamic_status(%d)\n", file_obj->uwAssociatedVMEMM));
// do what must be here in between -----------
pDevExt = (DEVICE_EXT *)(device_Obj->DeviceExtension);
SET_BUFFERS_METHOD_BUFFERED;
KdPrint(("ioctl_get_static_status(%d)\n", file_obj->uwAssociatedVMEMM));
// do what must be here in between -----------
if (OutputLength >= sizeof(PCIVME_DYNAMIC_STATUS))
{
USHORT temp;
pDynamicStatus = (PCIVME_DYNAMIC_STATUS *)pOutputBuffer;
pciada = pDevExt->vmemm[file_obj->uwAssociatedVMEMM];
pDynamicStatus->dwInterface = file_obj->uwAssociatedVMEMM;
temp = READ_REGISTER_USHORT(pciada->pwCntrl);
pDynamicStatus->wVMEMM_enable = ((temp & 0x0180) == 0x0180) ? 1 : 0;
pDynamicStatus->wVMEMM_connected = ((temp & 0x0c00) == 0x0800) ? 1 : 0;
temp = READ_REGISTER_USHORT(pciada->pwIntCSR);
pDynamicStatus->wPCIADAIrq = (temp & 0x0004) ? 1 : 0;
pDynamicStatus->wVMEMMIrq = (temp & 0x0020) ? 1 : 0;
}
else
Status = STATUS_BUFFER_TOO_SMALL;
// do what must be here in between --- end ---
COMPLETE_REQUEST;
KdPrint(("ioctl_get_dynamic_status(), Status = 0x%08x\n", Status));
return Status;
}
//------------------------------------------------------------------------
// get the next vector out of the vector queue
static NTSTATUS ioctl_read_vector(PDEVICE_OBJECT device_Obj, PIRP Irp, PIO_STACK_LOCATION IrpStack)
{
NTSTATUS Status = STATUS_SUCCESS;
ULONG irp_info = sizeof(PCIVME_VECTOR_RESPONSE);
PVOID pInputBuffer,pOutputBuffer;
ULONG InputLength, OutputLength;
PCIVME_VECTOR_RESPONSE *pVectorResponse;
PCIVME_VECTOR_REQUEST *pVectorRequest;
FILE_OBJ *file_obj = (FILE_OBJ *)Irp->Tail.Overlay.OriginalFileObject->FsContext;
KIRQL oldIrql;
BOOLEAN bPoll;
USHORT wRequestCount;
SET_BUFFERS_METHOD_BUFFERED;
KdPrint(("ioctl_read_vector(%d)\n", file_obj->uwAssociatedVMEMM));
pVectorRequest = (PCIVME_VECTOR_REQUEST *)pInputBuffer;
pVectorResponse = (PCIVME_VECTOR_RESPONSE *)pOutputBuffer;
// check the available room for vectors and correct if too less
if (OutputLength <
(sizeof(PCIVME_VECTOR_RESPONSE) +
(pVectorRequest->wRequestCount - 1) * sizeof(UCHAR)))
pVectorRequest->wRequestCount =
(USHORT)OutputLength - sizeof(PCIVME_VECTOR_RESPONSE) + sizeof(UCHAR);
// empty the inputbuffer as early as possible
wRequestCount = pVectorRequest->wRequestCount;
bPoll = pVectorRequest->bPoll;
// do what must be here in between -----------
if (OutputLength >= sizeof(PCIVME_VECTOR_RESPONSE)) // at least room for one
{
UCHAR bNumberOfElements;
UCHAR *pbVector = &pVectorResponse->bStatusID;
pVectorResponse->dwInterface = file_obj->uwAssociatedVMEMM;
bNumberOfElements = (UCHAR) NumberOfElements(file_obj->pIrqListHandle);
if ((bNumberOfElements) || (bPoll))
{
KdPrint(("Direct return (%d)\n", bNumberOfElements));
pVectorResponse->wCount = 0;
while ((bNumberOfElements) && (wRequestCount--))
{
bNumberOfElements = (UCHAR) PullElement(file_obj->pIrqListHandle,
(void *)pbVector);
pbVector++;
pVectorResponse->wCount++;
}
pVectorResponse->wPendingCount = bNumberOfElements;
pVectorResponse->bOverflow = CheckAndClearOverflow(file_obj->pIrqListHandle);
irp_info = sizeof(PCIVME_VECTOR_RESPONSE) +
sizeof(UCHAR) * (pVectorResponse->wCount - 1);
}
else // go in wait queue for an irq
{
IoAcquireCancelSpinLock(&oldIrql);
if (Irp->Cancel) // cancel while doing
{
KdPrint(("Canceld return (%d)\n", bNumberOfElements));
Status = STATUS_CANCELLED;
}
else
{
KdPrint(("Blocking return (%d)\n", bNumberOfElements));
InsertIRPtoQueue(device_Obj, Irp);
Status = STATUS_PENDING;
// mark irp as pending and return
IoMarkIrpPending(Irp);
IoSetCancelRoutine(Irp, CancelRequest);
} // if (Irp->Cancel) ...
IoReleaseCancelSpinLock(oldIrql);
}
}
else
Status = STATUS_BUFFER_TOO_SMALL;
// do what must be here in between --- end ---
COMPLETE_REQUEST;
KdPrint(("ioctl_read_vector(), Status = 0x%08x\n", Status));
return Status;
}
//------------------------------------------------------------------------
// control or read the VIC68A on the VMEMM
static NTSTATUS ioctl_access_VIC68A(PDEVICE_OBJECT device_Obj, PIRP Irp, PIO_STACK_LOCATION IrpStack)
{
NTSTATUS Status = STATUS_SUCCESS;
ULONG irp_info = sizeof(PCIVME_VIC68A_ACTION);
PVOID pInputBuffer,pOutputBuffer;
ULONG InputLength, OutputLength;
PCIADA *pciada;
DEVICE_EXT *pDevExt;
PCIVME_VIC68A_ACTION *pVIC68A_action_in;
PCIVME_VIC68A_ACTION *pVIC68A_action_out;
FILE_OBJ *file_obj = (FILE_OBJ *)Irp->Tail.Overlay.OriginalFileObject->FsContext;
pDevExt = (DEVICE_EXT *)(device_Obj->DeviceExtension);
SET_BUFFERS_METHOD_BUFFERED;
KdPrint(("ioctl_access_VIC68A(%d)\n", file_obj->uwAssociatedVMEMM));
// do what must be here in between -----------
pVIC68A_action_in = (PCIVME_VIC68A_ACTION *)pInputBuffer;
pVIC68A_action_out = (PCIVME_VIC68A_ACTION *)pOutputBuffer;
if ((pVIC68A_action_in->wRegisterAddress <= (USHORT)SRR) &&
((pVIC68A_action_in->wRegisterAddress & 0x03) == 3) &&
(OutputLength >= sizeof(PCIVME_VIC68A_ACTION)))
{
PUCHAR pbAddress;
UCHAR bByte=0;
KIRQL oldIrql;
pciada = pDevExt->vmemm[file_obj->uwAssociatedVMEMM];
pVIC68A_action_out = pVIC68A_action_in; // copy it
pbAddress = (PUCHAR)((ULONG)(pciada->pvVirtIfr) + VICBASE + pVIC68A_action_in->wRegisterAddress);
// lock other users out
KeAcquireSpinLock(&pciada->AccessLock, &oldIrql);
switch(pVIC68A_action_in->wAccessMode)
{
case VIC68A_WRITE: WRITE_REGISTER_UCHAR(pbAddress, pVIC68A_action_in->bContent);
bByte = READ_REGISTER_UCHAR(pbAddress);
break;
case VIC68A_WRITE_ONLY:
WRITE_REGISTER_UCHAR(pbAddress, pVIC68A_action_in->bContent);
break;
case VIC68A_OR: bByte = READ_REGISTER_UCHAR(pbAddress);
bByte |= pVIC68A_action_in->bContent;
WRITE_REGISTER_UCHAR(pbAddress, bByte);
bByte = READ_REGISTER_UCHAR(pbAddress);
break;
case VIC68A_AND: bByte = READ_REGISTER_UCHAR(pbAddress);
bByte &= pVIC68A_action_in->bContent;
WRITE_REGISTER_UCHAR(pbAddress, bByte);
bByte = READ_REGISTER_UCHAR(pbAddress);
break;
default: Status = STATUS_ILLEGAL_INSTRUCTION;
case VIC68A_READ: bByte = READ_REGISTER_UCHAR(pbAddress);
break;
}
// free lock
KeReleaseSpinLock(&pciada->AccessLock, oldIrql);
pVIC68A_action_out->bContent = bByte;
}
else
Status = STATUS_ILLEGAL_INSTRUCTION;
// do what must be here in between --- end ---
COMPLETE_REQUEST;
KdPrint(("ioctl_access_VIC68A(), Status = 0x%08x\n", Status));
return Status;
}
//------------------------------------------------------------------------
// if the interrupt is disabled for a blocking path, cancel the block
static void ReleaseBlockingIrp(PDEVICE_OBJECT device_Obj, PCIADA *pciada, PFILE_OBJ pFile_obj)
{
NTSTATUS Status = STATUS_CANCELLED;
PIRP Irp;
KIRQL oldIrqlCancel;
KIRQL oldIrqlList;
// beware off damage due to intercept with cancel of thread
IoAcquireCancelSpinLock(&oldIrqlCancel);
KeAcquireSpinLock(&pciada->IrqListLock, &oldIrqlList);
// get my associated packet
Irp = RemoveIRPfromQueue(device_Obj, pFile_obj);
if (Irp != (PIRP)NULL)
{
PCIVME_VECTOR_REQUEST *pVectorRequest = (PCIVME_VECTOR_REQUEST *)(Irp->AssociatedIrp.SystemBuffer);
PCIVME_VECTOR_RESPONSE *pVectorResponse = (PCIVME_VECTOR_RESPONSE *)pVectorRequest;
ULONG irp_info = sizeof(PCIVME_VECTOR_RESPONSE);
// pull the vectors off the fifo
pVectorResponse->wCount = 0;
pVectorResponse->wPendingCount = 0;
pVectorResponse->bOverflow = FALSE;
irp_info = sizeof(PCIVME_VECTOR_RESPONSE);
// release the cancel routine from this Irp
IoSetCancelRoutine(Irp, NULL);
COMPLETE_REQUEST;
}
// release the spin locks
KeReleaseSpinLock(&pciada->IrqListLock, oldIrqlList);
IoReleaseCancelSpinLock(oldIrqlCancel);
}
//------------------------------------------------------------------------
// switch the filling of the interrupt vector queue on or off, check the queue
static NTSTATUS ioctl_control_interrupts(PDEVICE_OBJECT device_Obj, PIRP Irp, PIO_STACK_LOCATION IrpStack)
{
NTSTATUS Status = STATUS_SUCCESS;
ULONG irp_info = sizeof(PCIVME_IRQ_CONTROL);
PVOID pInputBuffer,pOutputBuffer;
ULONG InputLength, OutputLength;
PCIADA *pciada;
DEVICE_EXT *pDevExt;
PCIVME_IRQ_CONTROL *pIrqControlIn;
PCIVME_IRQ_CONTROL *pIrqControlOut;
PFILE_OBJ pFile_obj = (PFILE_OBJ)Irp->Tail.Overlay.OriginalFileObject->FsContext;
pDevExt = (DEVICE_EXT *)(device_Obj->DeviceExtension);
SET_BUFFERS_METHOD_BUFFERED;
KdPrint(("ioctl_control_interrupts(%d)\n", pFile_obj->uwAssociatedVMEMM));
pIrqControlIn = (PCIVME_IRQ_CONTROL *)pInputBuffer;
pIrqControlOut = (PCIVME_IRQ_CONTROL *)pOutputBuffer;
pciada = pDevExt->vmemm[pFile_obj->uwAssociatedVMEMM];
// do what must be here in between -----------
if (pIrqControlIn->wEnable)
{
Status = insertQueueInList(pFile_obj, pciada);
if (!pciada->nInterruptHandlers)
{
KdPrint(("Interrupts enabled.\n"));
globalInterruptEnable(pciada);
pciada->nInterruptHandlers++;
}
}
else
{
if (pciada->nInterruptHandlers <= 1)
{
KdPrint(("Interrupts disabled.\n"));
globalInterruptDisable(pciada);
pciada->nInterruptHandlers = 0;
}
Status = removeQueueFromList(pFile_obj, pciada);
ReleaseBlockingIrp(device_Obj, pciada, pFile_obj);
}
// give back if the user grants space
if (OutputLength >= sizeof(PCIVME_IRQ_CONTROL))
{
pIrqControlOut->dwInterface = pFile_obj->uwAssociatedVMEMM;
pIrqControlOut->wEnable = pFile_obj->bQueueIrq;
}
// do what must be here in between --- end ---
COMPLETE_REQUEST;
KdPrint(("ioctl_control_interrupts(), Status = 0x%08x\n", Status));
return Status;
}
//------------------------------------------------------------------------
// generate a uninterruptible read-modify-write cycle
static NTSTATUS ioctl_TAS(PDEVICE_OBJECT device_Obj, PIRP Irp, PIO_STACK_LOCATION IrpStack)
{
NTSTATUS Status = STATUS_SUCCESS;
ULONG irp_info = sizeof(PCIVME_TAS_STRUCT);
PVOID pInputBuffer,pOutputBuffer;
ULONG InputLength, OutputLength;
PCIADA *pciada;
DEVICE_EXT *pDevExt;
FILE_OBJ *file_obj = (FILE_OBJ *)Irp->Tail.Overlay.OriginalFileObject->FsContext;
KIRQL oldIrql;
UCHAR tempContent;
PBOOLEAN pbPrevBusError;
PVOID pvPartialAdr;
pDevExt = (DEVICE_EXT *)(device_Obj->DeviceExtension);
SET_BUFFERS_METHOD_BUFFERED;
KdPrint(("ioctl_TAS(%d)\n", file_obj->uwAssociatedVMEMM));
// do what must be here in between -----------
if (OutputLength >= sizeof(PCIVME_TAS_STRUCT))
{
PCIVME_TAS_STRUCT *pTAS_struct_in;
PCIVME_TAS_STRUCT *pTAS_struct_out;
USHORT csr; // storage for old csr content
ULONG pageAddress; // intermediate for the page register content
UCHAR bAddressModifier;
pTAS_struct_in = (PCIVME_TAS_STRUCT *)pInputBuffer;
pTAS_struct_out = (PCIVME_TAS_STRUCT *)pOutputBuffer;
pTAS_struct_out = pTAS_struct_in;
pTAS_struct_out->dwInterface = file_obj->uwAssociatedVMEMM;
pciada = pDevExt->vmemm[file_obj->uwAssociatedVMEMM];
// take the file_obj associated modifier if greater than ...
bAddressModifier = (pTAS_struct_in->wModifier > 63) ?
file_obj->bAddressModifier : (UCHAR)pTAS_struct_in->wModifier;
// lock other users out
KeAcquireSpinLock(&pciada->AccessLock, &oldIrql);
// check for modifier (and set if needed)
if (pciada->bModifier != bAddressModifier)
{
WRITE_REGISTER_UCHAR(pciada->pbModifier, bAddressModifier);
pciada->bModifier = bAddressModifier;
}
// check for page address (and set if needed)
pageAddress = pTAS_struct_in->dwAddress & ~VME_ADR_MASK;
if (pageAddress != pciada->dwVMEPage)
{
WRITE_REGISTER_ULONG(pciada->pdwVMEAdr, pageAddress);
pciada->dwVMEPage = pageAddress;
}
// save VMEMM csr register and prepare for read modify write
csr = READ_REGISTER_USHORT(pciada->pwCSR);
WRITE_REGISTER_USHORT(pciada->pwCSR, (USHORT)(csr | FLAG_RMC));
// prepare the TAS
tempContent = pTAS_struct_in->bContent; // in and out point to same buffer
pvPartialAdr = (PVOID)((PUCHAR)pciada->pvVME + (pTAS_struct_in->dwAddress & VME_ADR_MASK));
// get prepared for bus errors
file_obj->bBusError = FALSE;
pbPrevBusError = ExchangePointer(&pciada->pbBusError, &file_obj->bBusError);
// do the TAS
readByte(&pTAS_struct_out->bContent , 1, pvPartialAdr);
writeByte(pvPartialAdr , 1, &tempContent);
readByte(&tempContent , 1, pvPartialAdr); // to overcome write on ..
// restore csr
WRITE_REGISTER_USHORT(pciada->pwCSR, csr);
// release the lock
KeReleaseSpinLock(&pciada->AccessLock, oldIrql);
ExchangePointer(&pciada->pbBusError, pbPrevBusError);
if (file_obj->bBusError) Status = STATUS_ACCESS_VIOLATION;
}
else
Status = STATUS_BUFFER_TOO_SMALL;
// do what must be here in between --- end ---
COMPLETE_REQUEST;
KdPrint(("ioctl_TAS(), Status = 0x%08x\n", Status));
return Status;
}
//------------------------------------------------------------------------
// make a VME reset
static NTSTATUS ioctl_reset(PDEVICE_OBJECT device_Obj, PIRP Irp, PIO_STACK_LOCATION IrpStack)
{
NTSTATUS Status = STATUS_SUCCESS;
ULONG irp_info = sizeof(PCIVME_RESET_RESULT);
PVOID pInputBuffer,pOutputBuffer;
ULONG InputLength, OutputLength;
DEVICE_EXT *pDevExt;
FILE_OBJ *file_obj = (FILE_OBJ *)Irp->Tail.Overlay.OriginalFileObject->FsContext;
pDevExt = (DEVICE_EXT *)(device_Obj->DeviceExtension);
SET_BUFFERS_METHOD_BUFFERED;
KdPrint(("ioctl_reset(%d)\n", file_obj->uwAssociatedVMEMM));
// do what must be here in between -----------
if (OutputLength >= sizeof(PCIVME_RESET_RESULT))
{
PCIVME_RESET_RESULT *pResetResult = (PCIVME_RESET_RESULT *)pOutputBuffer;
PCIVME_RESET_COMMAND *pResetCommand = (PCIVME_RESET_COMMAND *)pInputBuffer;
PCIADA *pciada = pDevExt->vmemm[file_obj->uwAssociatedVMEMM];
USHORT wIRQStatus;
USHORT wControl;
UCHAR *pbReset;
KIRQL oldIrql;
// set default result return size and contents
pResetResult->dwInterface = file_obj->uwAssociatedVMEMM;
if (pciada->dwLinkCount == 1)
{
// lock other users out
KeAcquireSpinLock(&pciada->AccessLock, &oldIrql);
// am I connected and switched on??
if ((READ_REGISTER_USHORT(pciada->pwCntrl) & 0x0980) == 0x0980)
{
// do command
switch (pResetCommand->wCommand)
{
case POLL_RESET_CMD:
break;
case VME_RESET_CMD:
WRITE_REGISTER_UCHAR(pciada->pbModifier, 0);
pbReset = (UCHAR *)((UCHAR *)pciada->pvVirtIfr +
(ULONG)VICBASE + (ULONG)SRR);
WRITE_REGISTER_UCHAR(pbReset, 0xf0); // make VME reset
break;
case LOCAL_RESET_CMD:
WRITE_REGISTER_UCHAR(pciada->pbModifier, 0);
WRITE_REGISTER_USHORT(pciada->pwIRQStat, LOCAL_RESET);
break;
case GLOBAL_RESET_CMD:
WRITE_REGISTER_UCHAR(pciada->pbModifier, 0);
WRITE_REGISTER_USHORT(pciada->pwIRQStat, GLOBAL_RESET);
break;
default: Status = STATUS_ILLEGAL_INSTRUCTION;
}
// save IRQ status of PCIADA and switch off PCIADA interrupts
wIRQStatus = READ_REGISTER_USHORT(pciada->pwIntCSR);
WRITE_REGISTER_USHORT(pciada->pwIntCSR, (USHORT)(wIRQStatus & ~0x0040));
// always poll reset status - access will sometimes generate PCIADA #2 interrupt
pResetResult->wResult = READ_REGISTER_UCHAR(pciada->pbModifier);
// reset any pending PCIADA interrupt #2
wControl = READ_REGISTER_USHORT(pciada->pwCntrl);
WRITE_REGISTER_USHORT(pciada->pwCntrl, (USHORT)(wControl & ~0x0100));
WRITE_REGISTER_USHORT(pciada->pwCntrl, wControl);
// restore IRQStatus
WRITE_REGISTER_USHORT(pciada->pwIntCSR, wIRQStatus);
}
else
Status = STATUS_ALREADY_DISCONNECTED;
// get other users free entry
KeReleaseSpinLock(&pciada->AccessLock, oldIrql);
}
else
Status = STATUS_UNSUCCESSFUL;
}
else
Status = STATUS_BUFFER_TOO_SMALL;
// do what must be here in between --- end ---
COMPLETE_REQUEST;
KdPrint(("ioctl_reset(), Status = 0x%08x\n", Status));
return Status;
}
//------------------------------------------------------------------------
// set parameter for this path for future access to VME
static NTSTATUS ioctl_access_para(PDEVICE_OBJECT device_Obj, PIRP Irp, PIO_STACK_LOCATION IrpStack)
{
NTSTATUS Status = STATUS_SUCCESS;
ULONG irp_info = 0;
PVOID pInputBuffer,pOutputBuffer;
ULONG InputLength, OutputLength;
PCIVME_ACCESS_COMMAND *pAccessPara;
FILE_OBJ *file_obj = (FILE_OBJ *)Irp->Tail.Overlay.OriginalFileObject->FsContext;
DEVICE_EXT *pDevExt = (DEVICE_EXT *)(device_Obj->DeviceExtension);
PCIADA *pciada = pDevExt->vmemm[file_obj->uwAssociatedVMEMM];
SET_BUFFERS_METHOD_BUFFERED;
KdPrint(("ioctl_access_para(%d)\n", file_obj->uwAssociatedVMEMM));
pAccessPara = (PCIVME_ACCESS_COMMAND *)pInputBuffer;
// do here in between what has to be done -----------------
file_obj->bAddressModifier = pAccessPara->bAddressModifier & MODIFIER_MASK;
file_obj->bAccessType = pAccessPara->bAccessType;
file_obj->bIncrement = pAccessPara->bIncrement;
file_obj->dwAddressMask = pAccessPara->bAccessType - 1;
// honor backward compatibility
if (file_obj->bAddressModifier & 0x30)
file_obj->dwAccessBase = 0;
else
file_obj->dwAccessBase = pAccessPara->dwAccessBase;
// access_type increment
// 1 0,1,2,3,4
// 2 0,2,4
// 4 0,4
if (pAccessPara->bIncrement % pAccessPara->bAccessType)
Status = STATUS_DATATYPE_MISALIGNMENT;
switch (pAccessPara->bAccessType)
{
case BYTE_ACCESS: file_obj->fRead = readByte;
file_obj->fWrite = writeByte;
break;
case WORD_ACCESS: file_obj->fRead = readWord;
file_obj->fWrite = writeWord;
break;
case LONG_ACCESS: if (pciada->bWordMode)
{
file_obj->fRead = readWord;
file_obj->fWrite = writeWord;
}
else
{
file_obj->fRead = readLong;
file_obj->fWrite = writeLong;
}
break;
default: Status = STATUS_UNSUCCESSFUL; break;
}
// do here in between what has to be done end -------------
COMPLETE_REQUEST;
KdPrint(("ioctl_access_para(), Status = 0x%08x\n", Status));
return Status;
}
//------------------------------------------------------------------------
// the ultimate jumptable for ioctl
//
NTSTATUS (*ioctl[])(PDEVICE_OBJECT device_Obj, PIRP Irp, PIO_STACK_LOCATION IrpStack) =
{
ioctl_init_hardware, // 0
ioctl_deinit_hardware, // 1
ioctl_dummy, // 2
ioctl_dummy, // 3
ioctl_get_static_status, // 4
ioctl_get_dynamic_status, // 5
ioctl_read_vector, // 6
ioctl_access_VIC68A, // 7
ioctl_dummy, // 8
ioctl_control_interrupts, // 9
ioctl_TAS, // 10
ioctl_dummy, // 11
ioctl_reset, // 12
ioctl_access_para // 13
};