NTSTATUS SerialIoControl( IN PDEVICE_OBJECT DeviceObject, IN PIRP Irp ) /*++ Routine Description: This routine provides the initial processing for all of the Ioctrls for the serial device. Arguments: DeviceObject - Pointer to the device object for this device Irp - Pointer to the IRP for the current request Return Value: The function value is the final status of the call --*/ { // // The status that gets returned to the caller and // set in the Irp. // NTSTATUS Status; // // The current stack location. This contains all of the // information we need to process this particular request. // PIO_STACK_LOCATION IrpSp; // // Just what it says. This is the serial specific device // extension of the device object create for the serial driver. // PSERIAL_DEVICE_EXTENSION Extension = DeviceObject->DeviceExtension; // // A temporary to hold the old IRQL so that it can be // restored once we complete/validate this request. // KIRQL OldIrql; SerialDump( SERIRPPATH, ("SERIAL: Dispatch entry for: %x\n",Irp) ); if (SerialCompleteIfError( DeviceObject, Irp ) != STATUS_SUCCESS) { return STATUS_CANCELLED; } IrpSp = IoGetCurrentIrpStackLocation(Irp); Irp->IoStatus.Information = 0L; Status = STATUS_SUCCESS; switch (IrpSp->Parameters.DeviceIoControl.IoControlCode) { case IOCTL_SERIAL_SET_BAUD_RATE : { ULONG BaudRate; // // Will hold the value of the appropriate divisor for // the requested baud rate. If the baudrate is invalid // (because the device won't support that baud rate) then // this value is undefined. // // Note: in one sense the concept of a valid baud rate // is cloudy. We could allow the user to request any // baud rate. We could then calculate the divisor needed // for that baud rate. As long as the divisor wasn't less // than one we would be "ok". (The percentage difference // between the "true" divisor and the "rounded" value given // to the hardware might make it unusable, but... ) It would // really be up to the user to "Know" whether the baud rate // is suitable. So much for theory, *We* only support a given // set of baud rates. // SHORT AppropriateDivisor; if (IrpSp->Parameters.DeviceIoControl.InputBufferLength < sizeof(SERIAL_BAUD_RATE)) { Status = STATUS_BUFFER_TOO_SMALL; break; } else { BaudRate = ((PSERIAL_BAUD_RATE)(Irp->AssociatedIrp.SystemBuffer))->BaudRate; } // // Get the baud rate from the irp. We pass it // to a routine which will set the correct divisor. // Status = SerialGetDivisorFromBaud( Extension->ClockRate, BaudRate, &AppropriateDivisor ); KeAcquireSpinLock( &Extension->ControlLock, &OldIrql ); if (NT_SUCCESS(Status)) { SERIAL_IOCTL_SYNC S; Extension->CurrentBaud = BaudRate; S.Extension = Extension; S.Data = (PVOID)AppropriateDivisor; KeSynchronizeExecution( Extension->Interrupt, SerialSetBaud, &S ); } KeReleaseSpinLock( &Extension->ControlLock, OldIrql ); break; } case IOCTL_SERIAL_GET_BAUD_RATE: { PSERIAL_BAUD_RATE Br = (PSERIAL_BAUD_RATE)Irp->AssociatedIrp.SystemBuffer; if (IrpSp->Parameters.DeviceIoControl.OutputBufferLength < sizeof(SERIAL_BAUD_RATE)) { Status = STATUS_BUFFER_TOO_SMALL; break; } KeAcquireSpinLock( &Extension->ControlLock, &OldIrql ); Br->BaudRate = Extension->CurrentBaud; KeReleaseSpinLock( &Extension->ControlLock, OldIrql ); Irp->IoStatus.Information = sizeof(SERIAL_BAUD_RATE); break; } case IOCTL_SERIAL_SET_LINE_CONTROL: { // // Points to the line control record in the Irp. // PSERIAL_LINE_CONTROL Lc = ((PSERIAL_LINE_CONTROL)(Irp->AssociatedIrp.SystemBuffer)); UCHAR LData; UCHAR LStop; UCHAR LParity; UCHAR Mask = 0xff; if (IrpSp->Parameters.DeviceIoControl.InputBufferLength < sizeof(SERIAL_LINE_CONTROL)) { Status = STATUS_BUFFER_TOO_SMALL; break; } switch (Lc->WordLength) { case 5: { LData = SERIAL_5_DATA; Mask = 0x1f; break; } case 6: { LData = SERIAL_6_DATA; Mask = 0x3f; break; } case 7: { LData = SERIAL_7_DATA; Mask = 0x7f; break; } case 8: { LData = SERIAL_8_DATA; break; } default: { Status = STATUS_INVALID_PARAMETER; goto DoneWithIoctl; } } switch (Lc->Parity) { case NO_PARITY: { LParity = SERIAL_NONE_PARITY; break; } case EVEN_PARITY: { LParity = SERIAL_EVEN_PARITY; break; } case ODD_PARITY: { LParity = SERIAL_ODD_PARITY; break; } case SPACE_PARITY: { LParity = SERIAL_SPACE_PARITY; break; } case MARK_PARITY: { LParity = SERIAL_MARK_PARITY; break; } default: { Status = STATUS_INVALID_PARAMETER; goto DoneWithIoctl; break; } } switch (Lc->StopBits) { case STOP_BIT_1: { LStop = SERIAL_1_STOP; break; } case STOP_BITS_1_5: { if (LData != SERIAL_5_DATA) { Status = STATUS_INVALID_PARAMETER; goto DoneWithIoctl; } LStop = SERIAL_1_5_STOP; break; } case STOP_BITS_2: { if (LData == SERIAL_5_DATA) { Status = STATUS_INVALID_PARAMETER; goto DoneWithIoctl; } LStop = SERIAL_2_STOP; break; } default: { Status = STATUS_INVALID_PARAMETER; goto DoneWithIoctl; } } KeAcquireSpinLock( &Extension->ControlLock, &OldIrql ); Extension->LineControl = (UCHAR)((Extension->LineControl & SERIAL_LCR_BREAK) | (LData | LParity | LStop)); Extension->ValidDataMask = Mask; KeSynchronizeExecution( Extension->Interrupt, SerialSetLineControl, Extension ); KeReleaseSpinLock( &Extension->ControlLock, OldIrql ); break; } case IOCTL_SERIAL_GET_LINE_CONTROL: { PSERIAL_LINE_CONTROL Lc = (PSERIAL_LINE_CONTROL)Irp->AssociatedIrp.SystemBuffer; if (IrpSp->Parameters.DeviceIoControl.OutputBufferLength < sizeof(SERIAL_LINE_CONTROL)) { Status = STATUS_BUFFER_TOO_SMALL; break; } KeAcquireSpinLock( &Extension->ControlLock, &OldIrql ); if ((Extension->LineControl & SERIAL_DATA_MASK) == SERIAL_5_DATA) { Lc->WordLength = 5; } else if ((Extension->LineControl & SERIAL_DATA_MASK) == SERIAL_6_DATA) { Lc->WordLength = 6; } else if ((Extension->LineControl & SERIAL_DATA_MASK) == SERIAL_7_DATA) { Lc->WordLength = 7; } else if ((Extension->LineControl & SERIAL_DATA_MASK) == SERIAL_8_DATA) { Lc->WordLength = 8; } if ((Extension->LineControl & SERIAL_PARITY_MASK) == SERIAL_NONE_PARITY) { Lc->Parity = NO_PARITY; } else if ((Extension->LineControl & SERIAL_PARITY_MASK) == SERIAL_ODD_PARITY) { Lc->Parity = ODD_PARITY; } else if ((Extension->LineControl & SERIAL_PARITY_MASK) == SERIAL_EVEN_PARITY) { Lc->Parity = EVEN_PARITY; } else if ((Extension->LineControl & SERIAL_PARITY_MASK) == SERIAL_MARK_PARITY) { Lc->Parity = MARK_PARITY; } else if ((Extension->LineControl & SERIAL_PARITY_MASK) == SERIAL_SPACE_PARITY) { Lc->Parity = SPACE_PARITY; } if (Extension->LineControl & SERIAL_2_STOP) { if (Lc->WordLength == 5) { Lc->StopBits = STOP_BITS_1_5; } else { Lc->StopBits = STOP_BITS_2; } } else { Lc->StopBits = STOP_BIT_1; } Irp->IoStatus.Information = sizeof(SERIAL_LINE_CONTROL); KeReleaseSpinLock( &Extension->ControlLock, OldIrql ); break; } case IOCTL_SERIAL_SET_TIMEOUTS: { PSERIAL_TIMEOUTS NewTimeouts = ((PSERIAL_TIMEOUTS)(Irp->AssociatedIrp.SystemBuffer)); if (IrpSp->Parameters.DeviceIoControl.InputBufferLength < sizeof(SERIAL_TIMEOUTS)) { Status = STATUS_BUFFER_TOO_SMALL; break; } if ((NewTimeouts->ReadIntervalTimeout == MAXULONG) && (NewTimeouts->ReadTotalTimeoutMultiplier == MAXULONG) && (NewTimeouts->ReadTotalTimeoutConstant == MAXULONG)) { Status = STATUS_INVALID_PARAMETER; break; } KeAcquireSpinLock( &Extension->ControlLock, &OldIrql ); Extension->Timeouts.ReadIntervalTimeout = NewTimeouts->ReadIntervalTimeout; Extension->Timeouts.ReadTotalTimeoutMultiplier = NewTimeouts->ReadTotalTimeoutMultiplier; Extension->Timeouts.ReadTotalTimeoutConstant = NewTimeouts->ReadTotalTimeoutConstant; Extension->Timeouts.WriteTotalTimeoutMultiplier = NewTimeouts->WriteTotalTimeoutMultiplier; Extension->Timeouts.WriteTotalTimeoutConstant = NewTimeouts->WriteTotalTimeoutConstant; KeReleaseSpinLock( &Extension->ControlLock, OldIrql ); break; } case IOCTL_SERIAL_GET_TIMEOUTS: { if (IrpSp->Parameters.DeviceIoControl.OutputBufferLength < sizeof(SERIAL_TIMEOUTS)) { Status = STATUS_BUFFER_TOO_SMALL; break; } KeAcquireSpinLock( &Extension->ControlLock, &OldIrql ); *((PSERIAL_TIMEOUTS)Irp->AssociatedIrp.SystemBuffer) = Extension->Timeouts; Irp->IoStatus.Information = sizeof(SERIAL_TIMEOUTS); KeReleaseSpinLock( &Extension->ControlLock, OldIrql ); break; } case IOCTL_SERIAL_SET_CHARS: { SERIAL_IOCTL_SYNC S; PSERIAL_CHARS NewChars = ((PSERIAL_CHARS)(Irp->AssociatedIrp.SystemBuffer)); if (IrpSp->Parameters.DeviceIoControl.InputBufferLength < sizeof(SERIAL_CHARS)) { Status = STATUS_BUFFER_TOO_SMALL; break; } // // The only thing that can be wrong with the chars // is that the xon and xoff characters are the // same. // #if 0 if (NewChars->XonChar == NewChars->XoffChar) { Status = STATUS_INVALID_PARAMETER; break; } #endif // // We acquire the control lock so that only // one request can GET or SET the characters // at a time. The sets could be synchronized // by the interrupt spinlock, but that wouldn't // prevent multiple gets at the same time. // S.Extension = Extension; S.Data = NewChars; KeAcquireSpinLock( &Extension->ControlLock, &OldIrql ); // // Under the protection of the lock, make sure that // the xon and xoff characters aren't the same as // the escape character. // if (Extension->EscapeChar) { if ((Extension->EscapeChar == NewChars->XonChar) || (Extension->EscapeChar == NewChars->XoffChar)) { Status = STATUS_INVALID_PARAMETER; KeReleaseSpinLock( &Extension->ControlLock, OldIrql ); break; } } KeSynchronizeExecution( Extension->Interrupt, SerialSetChars, &S ); KeReleaseSpinLock( &Extension->ControlLock, OldIrql ); break; } case IOCTL_SERIAL_GET_CHARS: { if (IrpSp->Parameters.DeviceIoControl.OutputBufferLength < sizeof(SERIAL_CHARS)) { Status = STATUS_BUFFER_TOO_SMALL; break; } KeAcquireSpinLock( &Extension->ControlLock, &OldIrql ); *((PSERIAL_CHARS)Irp->AssociatedIrp.SystemBuffer) = Extension->SpecialChars; Irp->IoStatus.Information = sizeof(SERIAL_CHARS); KeReleaseSpinLock( &Extension->ControlLock, OldIrql ); break; } case IOCTL_SERIAL_SET_DTR: case IOCTL_SERIAL_CLR_DTR: { // // We acquire the lock so that we can check whether // automatic dtr flow control is enabled. If it is // then we return an error since the app is not allowed // to touch this if it is automatic. // KeAcquireSpinLock( &Extension->ControlLock, &OldIrql ); if ((Extension->HandFlow.ControlHandShake & SERIAL_DTR_MASK) == SERIAL_DTR_HANDSHAKE) { Irp->IoStatus.Status = STATUS_INVALID_PARAMETER; } else { KeSynchronizeExecution( Extension->Interrupt, ((IrpSp->Parameters.DeviceIoControl.IoControlCode == IOCTL_SERIAL_SET_DTR)? (SerialSetDTR):(SerialClrDTR)), Extension ); } KeReleaseSpinLock( &Extension->ControlLock, OldIrql ); break; } case IOCTL_SERIAL_RESET_DEVICE: { break; } case IOCTL_SERIAL_SET_RTS: case IOCTL_SERIAL_CLR_RTS: { // // We acquire the lock so that we can check whether // automatic rts flow control or transmit toggleing // is enabled. If it is then we return an error since // the app is not allowed to touch this if it is automatic // or toggling. // KeAcquireSpinLock( &Extension->ControlLock, &OldIrql ); if (((Extension->HandFlow.FlowReplace & SERIAL_RTS_MASK) == SERIAL_RTS_HANDSHAKE) || ((Extension->HandFlow.FlowReplace & SERIAL_RTS_MASK) == SERIAL_TRANSMIT_TOGGLE)) { Irp->IoStatus.Status = STATUS_INVALID_PARAMETER; } else { KeSynchronizeExecution( Extension->Interrupt, ((IrpSp->Parameters.DeviceIoControl.IoControlCode == IOCTL_SERIAL_SET_RTS)? (SerialSetRTS):(SerialClrRTS)), Extension ); } KeReleaseSpinLock( &Extension->ControlLock, OldIrql ); break; } case IOCTL_SERIAL_SET_XOFF: { KeSynchronizeExecution( Extension->Interrupt, SerialPretendXoff, Extension ); break; } case IOCTL_SERIAL_SET_XON: { KeSynchronizeExecution( Extension->Interrupt, SerialPretendXon, Extension ); break; } case IOCTL_SERIAL_SET_BREAK_ON: { KeSynchronizeExecution( Extension->Interrupt, SerialTurnOnBreak, Extension ); break; } case IOCTL_SERIAL_SET_BREAK_OFF: { KeSynchronizeExecution( Extension->Interrupt, SerialTurnOffBreak, Extension ); break; } case IOCTL_SERIAL_SET_QUEUE_SIZE: { // // Type ahead buffer is fixed, so we just validate // the the users request is not bigger that our // own internal buffer size. // PSERIAL_QUEUE_SIZE Rs = ((PSERIAL_QUEUE_SIZE)(Irp->AssociatedIrp.SystemBuffer)); if (IrpSp->Parameters.DeviceIoControl.InputBufferLength < sizeof(SERIAL_QUEUE_SIZE)) { Status = STATUS_BUFFER_TOO_SMALL; break; } // // We have to allocate the memory for the new // buffer while we're still in the context of the // caller. We don't even try to protect this // with a lock because the value could be stale // as soon as we release the lock - The only time // we will know for sure is when we actually try // to do the resize. // if (Rs->InSize <= Extension->BufferSize) { Status = STATUS_SUCCESS; break; } try { IrpSp->Parameters.DeviceIoControl.Type3InputBuffer = ExAllocatePoolWithQuota( NonPagedPool, Rs->InSize ); } except (EXCEPTION_EXECUTE_HANDLER) { IrpSp->Parameters.DeviceIoControl.Type3InputBuffer = NULL; Status = GetExceptionCode(); } if (!IrpSp->Parameters.DeviceIoControl.Type3InputBuffer) { break; } // // Well the data passed was big enough. Do the request. // // There are two reason we place it in the read queue: // // 1) We want to serialize these resize requests so that // they don't contend with each other. // // 2) We want to serialize these requests with reads since // we don't want reads and resizes contending over the // read buffer. // return SerialStartOrQueue( Extension, Irp, &Extension->ReadQueue, &Extension->CurrentReadIrp, SerialStartRead ); break; } case IOCTL_SERIAL_GET_WAIT_MASK: { if (IrpSp->Parameters.DeviceIoControl.OutputBufferLength < sizeof(ULONG)) { Status = STATUS_BUFFER_TOO_SMALL; break; } // // Simple scalar read. No reason to acquire a lock. // Irp->IoStatus.Information = sizeof(ULONG); *((ULONG *)Irp->AssociatedIrp.SystemBuffer) = Extension->IsrWaitMask; break; } case IOCTL_SERIAL_SET_WAIT_MASK: { ULONG NewMask; SerialDump( SERDIAG3 | SERIRPPATH, ("SERIAL: In Ioctl processing for set mask\n") ); if (IrpSp->Parameters.DeviceIoControl.InputBufferLength < sizeof(ULONG)) { SerialDump( SERDIAG3, ("SERIAL: Invalid size fo the buffer %d\n", IrpSp->Parameters.DeviceIoControl.InputBufferLength) ); Status = STATUS_BUFFER_TOO_SMALL; break; } else { NewMask = *((ULONG *)Irp->AssociatedIrp.SystemBuffer); } // // Make sure that the mask only contains valid // waitable events. // if (NewMask & ~(SERIAL_EV_RXCHAR | SERIAL_EV_RXFLAG | SERIAL_EV_TXEMPTY | SERIAL_EV_CTS | SERIAL_EV_DSR | SERIAL_EV_RLSD | SERIAL_EV_BREAK | SERIAL_EV_ERR | SERIAL_EV_RING | SERIAL_EV_PERR | SERIAL_EV_RX80FULL | SERIAL_EV_EVENT1 | SERIAL_EV_EVENT2)) { SerialDump( SERDIAG3, ("SERIAL: Unknown mask %x\n",NewMask) ); Status = STATUS_INVALID_PARAMETER; break; } // // Either start this irp or put it on the // queue. // SerialDump( SERDIAG3 | SERIRPPATH, ("SERIAL: Starting or queuing set mask irp %x\n",Irp) ); return SerialStartOrQueue( Extension, Irp, &Extension->MaskQueue, &Extension->CurrentMaskIrp, SerialStartMask ); } case IOCTL_SERIAL_WAIT_ON_MASK: { SerialDump( SERDIAG3 | SERIRPPATH, ("SERIAL: In Ioctl processing for wait mask\n") ); if (IrpSp->Parameters.DeviceIoControl.OutputBufferLength < sizeof(ULONG)) { SerialDump( SERDIAG3, ("SERIAL: Invalid size fo the buffer %d\n", IrpSp->Parameters.DeviceIoControl.InputBufferLength) ); Status = STATUS_BUFFER_TOO_SMALL; break; } // // Either start this irp or put it on the // queue. // SerialDump( SERDIAG3 | SERIRPPATH, ("SERIAL: Starting or queuing wait mask irp %x\n",Irp) ); return SerialStartOrQueue( Extension, Irp, &Extension->MaskQueue, &Extension->CurrentMaskIrp, SerialStartMask ); } case IOCTL_SERIAL_IMMEDIATE_CHAR: { KIRQL OldIrql; if (IrpSp->Parameters.DeviceIoControl.InputBufferLength < sizeof(UCHAR)) { Status = STATUS_BUFFER_TOO_SMALL; break; } IoAcquireCancelSpinLock(&OldIrql); if (Extension->CurrentImmediateIrp) { Status = STATUS_INVALID_PARAMETER; IoReleaseCancelSpinLock(OldIrql); } else { // // We can queue the char. We need to set // a cancel routine because flow control could // keep the char from transmitting. Make sure // that the irp hasn't already been canceled. // if (Irp->Cancel) { IoReleaseCancelSpinLock(OldIrql); Status = STATUS_CANCELLED; } else { Extension->CurrentImmediateIrp = Irp; Extension->TotalCharsQueued++; IoReleaseCancelSpinLock(OldIrql); SerialStartImmediate(Extension); return STATUS_PENDING; } } break; } case IOCTL_SERIAL_PURGE: { ULONG Mask; if (IrpSp->Parameters.DeviceIoControl.InputBufferLength < sizeof(ULONG)) { Status = STATUS_BUFFER_TOO_SMALL; break; } // // Check to make sure that the mask only has // 0 or the other appropriate values. // Mask = *((ULONG *)(Irp->AssociatedIrp.SystemBuffer)); if ((!Mask) || (Mask & (~(SERIAL_PURGE_TXABORT | SERIAL_PURGE_RXABORT | SERIAL_PURGE_TXCLEAR | SERIAL_PURGE_RXCLEAR ) ) )) { Status = STATUS_INVALID_PARAMETER; break; } // // Either start this irp or put it on the // queue. // return SerialStartOrQueue( Extension, Irp, &Extension->PurgeQueue, &Extension->CurrentPurgeIrp, SerialStartPurge ); } case IOCTL_SERIAL_GET_HANDFLOW: { if (IrpSp->Parameters.DeviceIoControl.OutputBufferLength < sizeof(SERIAL_HANDFLOW)) { Status = STATUS_BUFFER_TOO_SMALL; break; } Irp->IoStatus.Information = sizeof(SERIAL_HANDFLOW); KeAcquireSpinLock( &Extension->ControlLock, &OldIrql ); *((PSERIAL_HANDFLOW)Irp->AssociatedIrp.SystemBuffer) = Extension->HandFlow; KeReleaseSpinLock( &Extension->ControlLock, OldIrql ); break; } case IOCTL_SERIAL_SET_HANDFLOW: { SERIAL_IOCTL_SYNC S; PSERIAL_HANDFLOW HandFlow = Irp->AssociatedIrp.SystemBuffer; // // Make sure that the hand shake and control is the // right size. // if (IrpSp->Parameters.DeviceIoControl.InputBufferLength < sizeof(SERIAL_HANDFLOW)) { Status = STATUS_BUFFER_TOO_SMALL; break; } // // Make sure that there are no invalid bits set in // the control and handshake. // if (HandFlow->ControlHandShake & SERIAL_CONTROL_INVALID) { Status = STATUS_INVALID_PARAMETER; break; } if (HandFlow->FlowReplace & SERIAL_FLOW_INVALID) { Status = STATUS_INVALID_PARAMETER; break; } // // Make sure that the app hasn't set an invlid DTR mode. // if ((HandFlow->ControlHandShake & SERIAL_DTR_MASK) == SERIAL_DTR_MASK) { Status = STATUS_INVALID_PARAMETER; break; } // // Make sure that haven't set totally invalid xon/xoff // limits. // if ((HandFlow->XonLimit < 0) || ((ULONG)HandFlow->XonLimit > Extension->BufferSize)) { Status = STATUS_INVALID_PARAMETER; break; } if ((HandFlow->XoffLimit < 0) || ((ULONG)HandFlow->XoffLimit > Extension->BufferSize)) { Status = STATUS_INVALID_PARAMETER; break; } S.Extension = Extension; S.Data = HandFlow; KeAcquireSpinLock( &Extension->ControlLock, &OldIrql ); // // Under the protection of the lock, make sure that // we aren't turning on error replacement when we // are doing line status/modem status insertion. // if (Extension->EscapeChar) { if (HandFlow->FlowReplace & SERIAL_ERROR_CHAR) { Status = STATUS_INVALID_PARAMETER; KeReleaseSpinLock( &Extension->ControlLock, OldIrql ); break; } } KeSynchronizeExecution( Extension->Interrupt, SerialSetHandFlow, &S ); KeReleaseSpinLock( &Extension->ControlLock, OldIrql ); break; } case IOCTL_SERIAL_GET_MODEMSTATUS: { SERIAL_IOCTL_SYNC S; if (IrpSp->Parameters.DeviceIoControl.OutputBufferLength < sizeof(ULONG)) { Status = STATUS_BUFFER_TOO_SMALL; break; } Irp->IoStatus.Information = sizeof(ULONG); S.Extension = Extension; S.Data = Irp->AssociatedIrp.SystemBuffer; KeAcquireSpinLock( &Extension->ControlLock, &OldIrql ); KeSynchronizeExecution( Extension->Interrupt, SerialGetModemUpdate, &S ); KeReleaseSpinLock( &Extension->ControlLock, OldIrql ); break; } case IOCTL_SERIAL_GET_DTRRTS: { ULONG ModemControl; if (IrpSp->Parameters.DeviceIoControl.OutputBufferLength < sizeof(ULONG)) { Status = STATUS_BUFFER_TOO_SMALL; break; } Irp->IoStatus.Information = sizeof(ULONG); Irp->IoStatus.Status = STATUS_SUCCESS; // // Reading this hardware has no effect on the device. // ModemControl = READ_MODEM_CONTROL(Extension->Controller); ModemControl &= SERIAL_DTR_STATE | SERIAL_RTS_STATE; *(PULONG)Irp->AssociatedIrp.SystemBuffer = ModemControl; break; } case IOCTL_SERIAL_GET_COMMSTATUS: { SERIAL_IOCTL_SYNC S; if (IrpSp->Parameters.DeviceIoControl.OutputBufferLength < sizeof(SERIAL_STATUS)) { Status = STATUS_BUFFER_TOO_SMALL; break; } Irp->IoStatus.Information = sizeof(SERIAL_STATUS); S.Extension = Extension; S.Data = Irp->AssociatedIrp.SystemBuffer; // // Acquire the cancel spin lock so nothing much // changes while were getting the state. // IoAcquireCancelSpinLock(&OldIrql); KeSynchronizeExecution( Extension->Interrupt, SerialGetCommStatus, &S ); IoReleaseCancelSpinLock(OldIrql); break; } case IOCTL_SERIAL_GET_PROPERTIES: { if (IrpSp->Parameters.DeviceIoControl.OutputBufferLength < sizeof(SERIAL_COMMPROP)) { Status = STATUS_BUFFER_TOO_SMALL; break; } // // No synchronization is required since this information // is "static". // SerialGetProperties( Extension, Irp->AssociatedIrp.SystemBuffer ); Irp->IoStatus.Information = sizeof(SERIAL_COMMPROP); Irp->IoStatus.Status = STATUS_SUCCESS; break; } case IOCTL_SERIAL_XOFF_COUNTER: { PSERIAL_XOFF_COUNTER Xc = Irp->AssociatedIrp.SystemBuffer; if (IrpSp->Parameters.DeviceIoControl.InputBufferLength < sizeof(SERIAL_XOFF_COUNTER)) { Status = STATUS_BUFFER_TOO_SMALL; break; } if (Xc->Counter <= 0) { Status = STATUS_INVALID_PARAMETER; break; } // // So far so good. Put the irp onto the write queue. // return SerialStartOrQueue( Extension, Irp, &Extension->WriteQueue, &Extension->CurrentWriteIrp, SerialStartWrite ); } case IOCTL_SERIAL_LSRMST_INSERT: { PUCHAR escapeChar = Irp->AssociatedIrp.SystemBuffer; // // Make sure we get a byte. // if (IrpSp->Parameters.DeviceIoControl.InputBufferLength < sizeof(UCHAR)) { Status = STATUS_BUFFER_TOO_SMALL; break; } KeAcquireSpinLock( &Extension->ControlLock, &OldIrql ); if (*escapeChar) { // // We've got some escape work to do. We will make sure that // the character is not the same as the Xon or Xoff character, // or that we are already doing error replacement. // if ((*escapeChar == Extension->SpecialChars.XoffChar) || (*escapeChar == Extension->SpecialChars.XonChar) || (Extension->HandFlow.FlowReplace & SERIAL_ERROR_CHAR)) { Status = STATUS_INVALID_PARAMETER; KeReleaseSpinLock( &Extension->ControlLock, OldIrql ); break; } } KeSynchronizeExecution( Extension->Interrupt, SerialSetEscapeChar, Irp ); KeReleaseSpinLock( &Extension->ControlLock, OldIrql ); break; } case IOCTL_SERIAL_CONFIG_SIZE: { if (IrpSp->Parameters.DeviceIoControl.OutputBufferLength < sizeof(ULONG)) { Status = STATUS_BUFFER_TOO_SMALL; break; } Irp->IoStatus.Information = sizeof(ULONG); Irp->IoStatus.Status = STATUS_SUCCESS; *(PULONG)Irp->AssociatedIrp.SystemBuffer = 0; break; } case IOCTL_SERIAL_GET_STATS: { if (IrpSp->Parameters.DeviceIoControl.OutputBufferLength < sizeof(SERIALPERF_STATS)) { Status = STATUS_BUFFER_TOO_SMALL; break; } Irp->IoStatus.Information = sizeof(SERIALPERF_STATS); Irp->IoStatus.Status = STATUS_SUCCESS; KeSynchronizeExecution( Extension->Interrupt, SerialGetStats, Irp ); break; } case IOCTL_SERIAL_CLEAR_STATS: { KeSynchronizeExecution( Extension->Interrupt, SerialClearStats, Extension ); break; } default: { Status = STATUS_INVALID_PARAMETER; break; } } DoneWithIoctl:; Irp->IoStatus.Status = Status; SerialDump( SERIRPPATH, ("SERIAL: Complete Irp: %x\n",Irp) ); IoCompleteRequest( Irp, 0 ); return Status; }
NTSTATUS SerialEvtDeviceD0Entry( IN WDFDEVICE Device, IN WDF_POWER_DEVICE_STATE PreviousState ) /*++ Routine Description: EvtDeviceD0Entry event callback must perform any operations that are necessary before the specified device is used. It will be called every time the hardware needs to be (re-)initialized. This includes after IRP_MN_START_DEVICE, IRP_MN_CANCEL_STOP_DEVICE, IRP_MN_CANCEL_REMOVE_DEVICE, IRP_MN_SET_POWER-D0. This function is not marked pageable because this function is in the device power up path. When a function is marked pagable and the code section is paged out, it will generate a page fault which could impact the fast resume behavior because the client driver will have to wait until the system drivers can service this page fault. This function runs at PASSIVE_LEVEL, even though it is not paged. A driver can optionally make this function pageable if DO_POWER_PAGABLE is set. Even if DO_POWER_PAGABLE isn't set, this function still runs at PASSIVE_LEVEL. In this case, though, the function absolutely must not do anything that will cause a page fault. Arguments: Device - Handle to a framework device object. PreviousState - Device power state which the device was in most recently. If the device is being newly started, this will be PowerDeviceUnspecified. Return Value: NTSTATUS --*/ { PSERIAL_DEVICE_EXTENSION deviceExtension; PSERIAL_DEVICE_STATE pDevState; SHORT divisor; SERIAL_IOCTL_SYNC S; SerialDbgPrintEx(TRACE_LEVEL_INFORMATION, DBG_POWER, "-->SerialEvtDeviceD0Entry - coming from %s\n", DbgDevicePowerString(PreviousState)); deviceExtension = SerialGetDeviceExtension (Device); pDevState = &deviceExtension->DeviceState; // // Restore the state of the UART. First, that involves disabling // interrupts both via OUT2 and IER. // WRITE_MODEM_CONTROL(deviceExtension, deviceExtension->Controller, 0); DISABLE_ALL_INTERRUPTS(deviceExtension, deviceExtension->Controller); // // Set the baud rate // SerialGetDivisorFromBaud(deviceExtension->ClockRate, deviceExtension->CurrentBaud, &divisor); S.Extension = deviceExtension; S.Data = (PVOID) (ULONG_PTR) divisor; #pragma prefast(suppress: __WARNING_INFERRED_IRQ_TOO_LOW, "PFD warning that we are calling interrupt synchronize routine directly. Suppress it because interrupt is disabled above.") SerialSetBaud(deviceExtension->WdfInterrupt, &S); // // Reset / Re-enable the FIFO's // if (deviceExtension->FifoPresent) { WRITE_FIFO_CONTROL(deviceExtension, deviceExtension->Controller, (UCHAR)0); READ_RECEIVE_BUFFER(deviceExtension, deviceExtension->Controller); WRITE_FIFO_CONTROL(deviceExtension, deviceExtension->Controller, (UCHAR)(SERIAL_FCR_ENABLE | deviceExtension->RxFifoTrigger | SERIAL_FCR_RCVR_RESET | SERIAL_FCR_TXMT_RESET)); } else { WRITE_FIFO_CONTROL(deviceExtension, deviceExtension->Controller, (UCHAR)0); } // // Restore a couple more registers // WRITE_INTERRUPT_ENABLE(deviceExtension, deviceExtension->Controller, pDevState->IER); WRITE_LINE_CONTROL(deviceExtension, deviceExtension->Controller, pDevState->LCR); // // Clear out any stale interrupts // READ_INTERRUPT_ID_REG(deviceExtension, deviceExtension->Controller); READ_LINE_STATUS(deviceExtension, deviceExtension->Controller); READ_MODEM_STATUS(deviceExtension, deviceExtension->Controller); // // TODO: move this code to EvtInterruptEnable. // if (deviceExtension->DeviceState.Reopen == TRUE) { SerialDbgPrintEx(TRACE_LEVEL_INFORMATION, DBG_POWER, "Reopening device\n"); SetDeviceIsOpened(deviceExtension, TRUE, FALSE); // // This enables interrupts on the device! // WRITE_MODEM_CONTROL(deviceExtension, deviceExtension->Controller, (UCHAR)(pDevState->MCR | SERIAL_MCR_OUT2)); // // Refire the state machine // DISABLE_ALL_INTERRUPTS(deviceExtension, deviceExtension->Controller); ENABLE_ALL_INTERRUPTS(deviceExtension, deviceExtension->Controller); } SerialDbgPrintEx(TRACE_LEVEL_INFORMATION, DBG_POWER, "<--SerialEvtDeviceD0Entry\n"); return STATUS_SUCCESS; }