/*++ Copyright (c) 2000 Microsoft Corporation Module Name: read.c Abstract: This module contains the code that is very specific to initialization and unload operations in the irenum driver Author: Brian Lieuallen, 7-13-2000 Environment: Kernel mode Revision History : --*/ #include "internal.h" VOID ReadCancelRoutine( PDEVICE_OBJECT DeviceObject, PIRP Irp ); VOID MoveDataFromBufferToIrp( PFDO_DEVICE_EXTENSION DeviceExtension ); VOID SeeIfIrpShouldBeCompleted( PFDO_DEVICE_EXTENSION DeviceExtension ); NTSTATUS IrCommRead( PDEVICE_OBJECT DeviceObject, PIRP Irp ) { PFDO_DEVICE_EXTENSION DeviceExtension=(PFDO_DEVICE_EXTENSION)DeviceObject->DeviceExtension; NTSTATUS Status=STATUS_SUCCESS; D_TRACE(DbgPrint("IRCOMM: IrCommRead\n");) if (DeviceExtension->Removing) { // // the device has been removed, no more irps // Irp->IoStatus.Status=STATUS_DEVICE_REMOVED; IoCompleteRequest(Irp,IO_NO_INCREMENT); return STATUS_DEVICE_REMOVED; } #if DBG { PIO_STACK_LOCATION IrpSp = IoGetCurrentIrpStackLocation(Irp); RtlFillMemory( Irp->AssociatedIrp.SystemBuffer, IrpSp->Parameters.Read.Length, 0xf1 ); } #endif IoMarkIrpPending(Irp); Irp->IoStatus.Information=0; QueuePacket(&DeviceExtension->Read.Queue,Irp,FALSE); return STATUS_PENDING; } VOID ReadStartRoutine( PVOID Context, PIRP Irp ) { PFDO_DEVICE_EXTENSION DeviceExtension=(PFDO_DEVICE_EXTENSION)Context; PIO_STACK_LOCATION IrpSp = IoGetCurrentIrpStackLocation(Irp); KIRQL OldIrql; KIRQL CancelIrql; Irp->IoStatus.Information=0; Irp->IoStatus.Status=STATUS_TIMEOUT; KeAcquireSpinLock( &DeviceExtension->Read.ReadLock, &OldIrql ); ASSERT(!DeviceExtension->Read.TotalTimerSet); ASSERT(!DeviceExtension->Read.IntervalTimerSet); // // add one refcount for this routine. // DeviceExtension->Read.IrpRefCount=1; DeviceExtension->Read.CurrentIrp=Irp; DeviceExtension->Read.IrpShouldBeCompleted=FALSE; DeviceExtension->Read.IrpShouldBeCompletedWithAnyData=FALSE; IoAcquireCancelSpinLock(&CancelIrql); if (Irp->Cancel) { // // it has already been canceled, just mark it to complete // DeviceExtension->Read.IrpShouldBeCompleted=FALSE; } DeviceExtension->Read.IrpRefCount++; IoSetCancelRoutine(Irp,ReadCancelRoutine); IoReleaseCancelSpinLock(CancelIrql); if ((DeviceExtension->TimeOuts.ReadIntervalTimeout == MAXULONG) && (DeviceExtension->TimeOuts.ReadTotalTimeoutMultiplier == 0) && (DeviceExtension->TimeOuts.ReadTotalTimeoutConstant == 0)) { // // The set of timeouts means that the request should simply return with // whatever data is availible // DeviceExtension->Read.IrpShouldBeCompleted=TRUE; Irp->IoStatus.Status=STATUS_SUCCESS; } if ((DeviceExtension->TimeOuts.ReadTotalTimeoutMultiplier != 0) || (DeviceExtension->TimeOuts.ReadTotalTimeoutConstant != 0)) { // // need a total timeout // LARGE_INTEGER DueTime; ULONG TimeoutMultiplier=DeviceExtension->TimeOuts.ReadTotalTimeoutMultiplier; if ((TimeoutMultiplier == MAXULONG) && (DeviceExtension->TimeOuts.ReadIntervalTimeout == MAXULONG)) { // // this means that the read should complete as soon as any data is read, or the constant timeout // expires. // DeviceExtension->Read.IrpShouldBeCompletedWithAnyData=TRUE; TimeoutMultiplier=0; } DueTime.QuadPart= ((LONGLONG)(DeviceExtension->TimeOuts.ReadTotalTimeoutConstant + (TimeoutMultiplier * IrpSp->Parameters.Read.Length))) * -10000; KeSetTimer( &DeviceExtension->Read.TotalTimer, DueTime, &DeviceExtension->Read.TotalTimerDpc ); DeviceExtension->Read.TotalTimerSet=TRUE; DeviceExtension->Read.IrpRefCount++; } DeviceExtension->Read.IntervalTimeOut=0; if ((DeviceExtension->TimeOuts.ReadIntervalTimeout != 0) && (DeviceExtension->TimeOuts.ReadIntervalTimeout != MAXULONG)) { // // capture the interval timer we will use for this irp // DeviceExtension->Read.IntervalTimeOut=DeviceExtension->TimeOuts.ReadIntervalTimeout; } KeReleaseSpinLock( &DeviceExtension->Read.ReadLock, OldIrql ); MoveDataFromBufferToIrp( DeviceExtension ); SeeIfIrpShouldBeCompleted( DeviceExtension ); return; } BOOLEAN CopyMemoryAndCheckForChar( PUCHAR Destination, PUCHAR Source, ULONG Length, UCHAR CharacterToCheck ) { PUCHAR EndPoint=Destination+Length; BOOLEAN ReturnValue=FALSE; while (Destination < EndPoint) { *Destination = *Source; if (*Destination == CharacterToCheck) { // DbgPrint("Got event char\n"); ReturnValue=TRUE; } Destination++; Source++; } return ReturnValue; } NTSTATUS DataAvailibleHandler( PVOID Context, PUCHAR Buffer, ULONG BytesAvailible, PULONG BytesUsed ) { PFDO_DEVICE_EXTENSION DeviceExtension=(PFDO_DEVICE_EXTENSION)Context; ULONG BytesToCopy; ULONG BytesToCopyInFirstPass; BOOLEAN FoundEventCharacter; BOOLEAN FoundEventCharacter2=FALSE; BOOLEAN EightyPercentFull=FALSE; KIRQL OldIrql; *BytesUsed = 0; ASSERT(BytesAvailible <= INPUT_BUFFER_SIZE); KeAcquireSpinLock( &DeviceExtension->Read.ReadLock, &OldIrql ); // // find out how many bytes can be copied // BytesToCopy = min(BytesAvailible , INPUT_BUFFER_SIZE - DeviceExtension->Read.BytesInBuffer); if (BytesToCopy < BytesAvailible) { if (DeviceExtension->Read.DtrState) { // // only take the whole packet, so we don't have to worry about how to figure out if // the ircomm control info in on the front of the buffer // DeviceExtension->Read.RefusedDataIndication=TRUE; D_TRACE1(DbgPrint("IRCOMM: data refused\n");) KeReleaseSpinLock( &DeviceExtension->Read.ReadLock, OldIrql ); *BytesUsed=0; return STATUS_DATA_NOT_ACCEPTED; } else { // // dtr is low, just throw the data away as we are probably trying to hangup // D_TRACE1(DbgPrint("IRCOMM: overflow data thrown away because dtr low - %d\n",BytesAvailible);) KeReleaseSpinLock( &DeviceExtension->Read.ReadLock, OldIrql ); *BytesUsed=BytesAvailible; return STATUS_SUCCESS; } } // // see how much more is left before we wrap the buffer // BytesToCopyInFirstPass= (ULONG)(&DeviceExtension->Read.InputBuffer[INPUT_BUFFER_SIZE] - DeviceExtension->Read.NextEmptyByte); // // only can copy as many as are actually availible // BytesToCopyInFirstPass= min( BytesToCopy , BytesToCopyInFirstPass ); FoundEventCharacter=CopyMemoryAndCheckForChar( DeviceExtension->Read.NextEmptyByte, Buffer, BytesToCopyInFirstPass, DeviceExtension->SerialChars.EventChar ); DeviceExtension->Read.NextEmptyByte += BytesToCopyInFirstPass; *BytesUsed += BytesToCopyInFirstPass; DeviceExtension->Read.BytesInBuffer += BytesToCopyInFirstPass; if (BytesToCopyInFirstPass < BytesToCopy) { // // must have wrapped, copy the rest // ULONG BytesToCopyInSecondPass=BytesToCopy-BytesToCopyInFirstPass; ASSERT(DeviceExtension->Read.NextEmptyByte == &DeviceExtension->Read.InputBuffer[INPUT_BUFFER_SIZE]); // // back to the beggining // DeviceExtension->Read.NextEmptyByte=&DeviceExtension->Read.InputBuffer[0]; FoundEventCharacter2 =CopyMemoryAndCheckForChar( DeviceExtension->Read.NextEmptyByte, Buffer+BytesToCopyInFirstPass, BytesToCopyInSecondPass, DeviceExtension->SerialChars.EventChar ); DeviceExtension->Read.NextEmptyByte += BytesToCopyInSecondPass; *BytesUsed += BytesToCopyInSecondPass; DeviceExtension->Read.BytesInBuffer += BytesToCopyInSecondPass; } if (DeviceExtension->Read.CurrentIrp != NULL) { // // there is currently a read irp, Check to see if we should set an interval timeout // if (DeviceExtension->Read.IntervalTimerSet) { // // the time is already set, cancel it first // BOOLEAN Canceled; Canceled=KeCancelTimer( &DeviceExtension->Read.IntervalTimer ); if (Canceled) { // // the timer had not fired yet, reset these since they will be changed below // DeviceExtension->Read.IntervalTimerSet=FALSE; DeviceExtension->Read.IrpRefCount--; } else { // // the time has already expired. it will complete the current irp // } } // // either this is the first time we are setting the timer, or we tried to // cancel a previous version of it. If we did cancel it this is the same as // it not being set. If it was set before and we did not cancel it, then we // won't set a new one since the timer DPC is queued to run and will complete // the irp // if ((DeviceExtension->Read.IntervalTimeOut != 0) && !DeviceExtension->Read.IntervalTimerSet) { // // we need an interval timer // LARGE_INTEGER DueTime; DueTime.QuadPart= (LONGLONG)DeviceExtension->Read.IntervalTimeOut * -10000; KeSetTimer( &DeviceExtension->Read.IntervalTimer, DueTime, &DeviceExtension->Read.IntervalTimerDpc ); DeviceExtension->Read.IntervalTimerSet=TRUE; DeviceExtension->Read.IrpRefCount++; } } EightyPercentFull= DeviceExtension->Read.BytesInBuffer > (INPUT_BUFFER_SIZE * 8)/10; KeReleaseSpinLock( &DeviceExtension->Read.ReadLock, OldIrql ); // // try to move the buffered data to a read irp // MoveDataFromBufferToIrp( DeviceExtension ); SeeIfIrpShouldBeCompleted( DeviceExtension ); EventNotification( DeviceExtension, SERIAL_EV_RXCHAR | ((FoundEventCharacter || FoundEventCharacter) ? SERIAL_EV_RXFLAG : 0) | ((EightyPercentFull) ? SERIAL_EV_RX80FULL : 0) ); ASSERT(*BytesUsed == BytesAvailible); return STATUS_SUCCESS; } #if 0 VOID DebugCopyMemory( PUCHAR Destination, PUCHAR Source, ULONG Length ) { PUCHAR EndPoint=Destination+Length; while (Destination < EndPoint) { *Destination = *Source; if ((*Source == 0xe1) || (*Source == 0xe2)) { DbgPrint("IRCOMM: bad data at %p\n",Source); DbgBreakPoint(); } Destination++; Source++; } return; } #endif VOID MoveDataFromBufferToIrp( PFDO_DEVICE_EXTENSION DeviceExtension ) { KIRQL OldIrql; BOOLEAN RequestDataIndications=FALSE; KeAcquireSpinLock( &DeviceExtension->Read.ReadLock, &OldIrql ); if (DeviceExtension->Read.CurrentIrp != NULL) { PIRP Irp = DeviceExtension->Read.CurrentIrp; PIO_STACK_LOCATION IrpSp = IoGetCurrentIrpStackLocation(Irp); ULONG TotalBytesToCopy; ULONG BytesToCopyInFirstPass; ULONG BytesToCopyInSecondPass; ULONG BytesToEndOfBuffer; // // find the max number of bytes that can be copied // TotalBytesToCopy = min(DeviceExtension->Read.BytesInBuffer , IrpSp->Parameters.Read.Length - (ULONG)Irp->IoStatus.Information ); // // Find out how many bytes are between the first filled byte and the end of the buffer // BytesToEndOfBuffer= (ULONG)(&DeviceExtension->Read.InputBuffer[INPUT_BUFFER_SIZE] - DeviceExtension->Read.NextFilledByte); // // If the buffer wraps, the bytes to the end will be the limiting factor, otherwise // it does not wrap and in that case the total bytes will be the limiting factor // BytesToCopyInFirstPass= min(TotalBytesToCopy , BytesToEndOfBuffer); RtlCopyMemory( (PUCHAR)Irp->AssociatedIrp.SystemBuffer + Irp->IoStatus.Information, DeviceExtension->Read.NextFilledByte, BytesToCopyInFirstPass ); #if DBG RtlFillMemory( DeviceExtension->Read.NextFilledByte, BytesToCopyInFirstPass, 0xe1 ); #endif DeviceExtension->Read.NextFilledByte += BytesToCopyInFirstPass; DeviceExtension->Read.BytesInBuffer -= BytesToCopyInFirstPass; Irp->IoStatus.Information+= BytesToCopyInFirstPass; BytesToCopyInSecondPass= TotalBytesToCopy - BytesToCopyInFirstPass; if (BytesToCopyInSecondPass > 0) { // // back to the begining of the buffer // ASSERT( DeviceExtension->Read.NextFilledByte == &DeviceExtension->Read.InputBuffer[INPUT_BUFFER_SIZE]); DeviceExtension->Read.NextFilledByte=&DeviceExtension->Read.InputBuffer[0]; RtlCopyMemory( (PUCHAR)Irp->AssociatedIrp.SystemBuffer + Irp->IoStatus.Information, DeviceExtension->Read.NextFilledByte, BytesToCopyInSecondPass ); #if DBG RtlFillMemory( DeviceExtension->Read.NextFilledByte, BytesToCopyInSecondPass, 0xe2 ); #endif DeviceExtension->Read.NextFilledByte += BytesToCopyInSecondPass; DeviceExtension->Read.BytesInBuffer -= BytesToCopyInSecondPass; Irp->IoStatus.Information+= BytesToCopyInSecondPass; } if (Irp->IoStatus.Information == IrpSp->Parameters.Read.Length) { // // the irp is full, set status to success // Irp->IoStatus.Status=STATUS_SUCCESS; // // since it is now full, it can complete now // DeviceExtension->Read.IrpShouldBeCompleted=TRUE; } if (DeviceExtension->Read.IrpShouldBeCompletedWithAnyData && (Irp->IoStatus.Information > 0)) { // // the client wants the irp to complete when any data is present // Irp->IoStatus.Status=STATUS_SUCCESS; // // make complete // DeviceExtension->Read.IrpShouldBeCompleted=TRUE; } } if ((DeviceExtension->Read.BytesInBuffer == 0) && DeviceExtension->Read.RefusedDataIndication) { // // the buffer is empty now and we previous refused some indicated data // DbgPrint("IRCOMM: requesting data\n"); DeviceExtension->Read.RefusedDataIndication=FALSE; RequestDataIndications=TRUE; } KeReleaseSpinLock( &DeviceExtension->Read.ReadLock, OldIrql ); if (RequestDataIndications) { IndicateReceiveBufferSpaceAvailible( DeviceExtension->ConnectionHandle ); } return; } VOID ReadCancelRoutine( PDEVICE_OBJECT DeviceObject, PIRP Irp ) { PFDO_DEVICE_EXTENSION DeviceExtension=DeviceObject->DeviceExtension; KIRQL OldIrql; IoReleaseCancelSpinLock(Irp->CancelIrql); KeAcquireSpinLock( &DeviceExtension->Read.ReadLock, &OldIrql ); DeviceExtension->Read.IrpRefCount--; DeviceExtension->Read.IrpShouldBeCompleted=TRUE; KeReleaseSpinLock( &DeviceExtension->Read.ReadLock, OldIrql ); SeeIfIrpShouldBeCompleted( DeviceExtension ); return; } VOID IntervalTimeProc( PKDPC Dpc, PVOID Context, PVOID SystemParam1, PVOID SystemParam2 ) { PFDO_DEVICE_EXTENSION DeviceExtension=Context; KIRQL OldIrql; PIRP Irp=NULL; D_ERROR(DbgPrint("IRCOMM: Interval timeout expired\n");) MoveDataFromBufferToIrp( DeviceExtension ); KeAcquireSpinLock( &DeviceExtension->Read.ReadLock, &OldIrql ); ASSERT(DeviceExtension->Read.IntervalTimerSet); // // this timer is not set anymore // DeviceExtension->Read.IntervalTimerSet=FALSE; DeviceExtension->Read.IrpRefCount--; DeviceExtension->Read.IrpShouldBeCompleted=TRUE; KeReleaseSpinLock( &DeviceExtension->Read.ReadLock, OldIrql ); SeeIfIrpShouldBeCompleted( DeviceExtension ); return; } VOID TotalTimerProc( PKDPC Dpc, PVOID Context, PVOID SystemParam1, PVOID SystemParam2 ) { PFDO_DEVICE_EXTENSION DeviceExtension=Context; KIRQL OldIrql; D_TRACE(DbgPrint("IRCOMM: Total timeout expired\n");) MoveDataFromBufferToIrp( DeviceExtension ); KeAcquireSpinLock( &DeviceExtension->Read.ReadLock, &OldIrql ); ASSERT(DeviceExtension->Read.TotalTimerSet); // // this timer is not set anymore // DeviceExtension->Read.TotalTimerSet=FALSE; DeviceExtension->Read.IrpRefCount--; DeviceExtension->Read.IrpShouldBeCompleted=TRUE; KeReleaseSpinLock( &DeviceExtension->Read.ReadLock, OldIrql ); SeeIfIrpShouldBeCompleted( DeviceExtension ); return; } VOID SeeIfIrpShouldBeCompleted( PFDO_DEVICE_EXTENSION DeviceExtension ) { KIRQL OldIrql; PIRP Irp=NULL; KeAcquireSpinLock( &DeviceExtension->Read.ReadLock, &OldIrql ); if (DeviceExtension->Read.CurrentIrp != NULL) { // // There is an irp present // if (DeviceExtension->Read.IrpShouldBeCompleted) { // // either the irp is full, or a timer has expired. We are done with this irp in anycase. // PVOID OldCancelRoutine; // // try to cancel the timers, since we want to complete the irp now. // if (DeviceExtension->Read.IntervalTimerSet) { BOOLEAN Canceled; Canceled=KeCancelTimer( &DeviceExtension->Read.IntervalTimer ); if (Canceled) { // // We ended up canceling the timer // DeviceExtension->Read.IrpRefCount--; DeviceExtension->Read.IntervalTimerSet=FALSE; } else { // // The timer is already running, we will just let it complete // and do the clean up. // } } if (DeviceExtension->Read.TotalTimerSet) { BOOLEAN Canceled; Canceled=KeCancelTimer( &DeviceExtension->Read.TotalTimer ); if (Canceled) { // // We ended up canceling the timer // DeviceExtension->Read.IrpRefCount--; DeviceExtension->Read.TotalTimerSet=FALSE; } else { // // The timer is already running, we will just let it complete // and do the clean up. // } } OldCancelRoutine=IoSetCancelRoutine(DeviceExtension->Read.CurrentIrp,NULL); if (OldCancelRoutine != NULL) { // // the irp has not been canceled yet, and will not be now // DeviceExtension->Read.IrpRefCount--; } else { // // the cancel routine has run and decremented the ref count for us // } ASSERT(DeviceExtension->Read.IrpRefCount > 0); if (DeviceExtension->Read.IrpRefCount == 1) { // // We can complete the irp now // ASSERT(!DeviceExtension->Read.TotalTimerSet); ASSERT(!DeviceExtension->Read.IntervalTimerSet); #if DBG DeviceExtension->Read.IrpRefCount=0; #endif Irp=DeviceExtension->Read.CurrentIrp; DeviceExtension->Read.CurrentIrp=NULL; InterlockedExchangeAdd(&DeviceExtension->Read.BytesRead,(LONG)Irp->IoStatus.Information); } } } KeReleaseSpinLock( &DeviceExtension->Read.ReadLock, OldIrql ); if (Irp != NULL) { // // we should complete this irp now // IoCompleteRequest(Irp,IO_NO_INCREMENT); StartNextPacket(&DeviceExtension->Read.Queue); } return; } VOID ReadPurge( PFDO_DEVICE_EXTENSION DeviceExtension, ULONG Flags ) { KIRQL OldIrql; BOOLEAN RequestDataIndications=FALSE; if (Flags == READ_PURGE_CLEAR_BUFFER) { // // the caller wants the buffer cleared // KeAcquireSpinLock( &DeviceExtension->Read.ReadLock, &OldIrql ); DeviceExtension->Read.BytesInBuffer=0; DeviceExtension->Read.NextFilledByte=&DeviceExtension->Read.InputBuffer[0]; DeviceExtension->Read.NextEmptyByte=&DeviceExtension->Read.InputBuffer[0]; #if DBG RtlFillMemory( &DeviceExtension->Read.InputBuffer[0], sizeof(DeviceExtension->Read.InputBuffer), 0xf7 ); #endif if (DeviceExtension->Read.RefusedDataIndication) { // // the buffer is empty now and we previous refused some indicated data // DbgPrint("IRCOMM: requesting data from purge\n"); DeviceExtension->Read.RefusedDataIndication=FALSE; RequestDataIndications=TRUE; } KeReleaseSpinLock( &DeviceExtension->Read.ReadLock, OldIrql ); } if (Flags == READ_PURGE_ABORT_IRP) { // // the caller wants the current irp to complete // DeviceExtension->Read.IrpShouldBeCompleted=TRUE; SeeIfIrpShouldBeCompleted( DeviceExtension ); } if (RequestDataIndications) { IndicateReceiveBufferSpaceAvailible( DeviceExtension->ConnectionHandle ); } return; }