void com_putchar(char ch)
{
if (ch == '\n') {
com_putchar('\r');
}
while ((READ_PORT_UCHAR (pv(SER_LSR(COM_BASE))) & SR_LSR_TBE) == 0);
WRITE_PORT_UCHAR(pv(SER_THR(COM_BASE)), ch);
}
VOID NTAPI
SerialSendByte(
IN PKDPC Dpc,
IN PVOID pDeviceExtension, // real type PSERIAL_DEVICE_EXTENSION
IN PVOID Unused1,
IN PVOID Unused2)
{
PSERIAL_DEVICE_EXTENSION DeviceExtension;
PUCHAR ComPortBase;
UCHAR Byte;
KIRQL Irql;
UCHAR IER;
NTSTATUS Status;
DeviceExtension = (PSERIAL_DEVICE_EXTENSION)pDeviceExtension;
ComPortBase = ULongToPtr(DeviceExtension->BaseAddress);
KeAcquireSpinLock(&DeviceExtension->OutputBufferLock, &Irql);
while (!IsCircularBufferEmpty(&DeviceExtension->OutputBuffer)
&& READ_PORT_UCHAR(SER_LSR(ComPortBase)) & SR_LSR_THR_EMPTY)
{
Status = PopCircularBufferEntry(&DeviceExtension->OutputBuffer, &Byte);
if (!NT_SUCCESS(Status))
break;
WRITE_PORT_UCHAR(SER_THR(ComPortBase), Byte);
INFO_(SERIAL, "Byte sent to COM%lu: 0x%02x\n",
DeviceExtension->ComPort, Byte);
DeviceExtension->SerialPerfStats.TransmittedCount++;
}
if (!IsCircularBufferEmpty(&DeviceExtension->OutputBuffer))
{
/* allow new interrupts */
IER = READ_PORT_UCHAR(SER_IER(ComPortBase));
WRITE_PORT_UCHAR(SER_IER(ComPortBase), IER | SR_IER_THR_EMPTY);
}
KeReleaseSpinLock(&DeviceExtension->OutputBufferLock, Irql);
}
VOID NTAPI
SerialReceiveByte(
IN PKDPC Dpc,
IN PVOID pDeviceExtension, // real type PSERIAL_DEVICE_EXTENSION
IN PVOID Unused1,
IN PVOID Unused2)
{
PSERIAL_DEVICE_EXTENSION DeviceExtension;
PUCHAR ComPortBase;
UCHAR Byte;
KIRQL Irql;
UCHAR IER;
NTSTATUS Status;
DeviceExtension = (PSERIAL_DEVICE_EXTENSION)pDeviceExtension;
ComPortBase = ULongToPtr(DeviceExtension->BaseAddress);
KeAcquireSpinLock(&DeviceExtension->InputBufferLock, &Irql);
while (READ_PORT_UCHAR(SER_LSR(ComPortBase)) & SR_LSR_DATA_RECEIVED)
{
Byte = READ_PORT_UCHAR(SER_RBR(ComPortBase));
INFO_(SERIAL, "Byte received on COM%lu: 0x%02x\n",
DeviceExtension->ComPort, Byte);
Status = PushCircularBufferEntry(&DeviceExtension->InputBuffer, Byte);
if (NT_SUCCESS(Status))
DeviceExtension->SerialPerfStats.ReceivedCount++;
else
DeviceExtension->SerialPerfStats.BufferOverrunErrorCount++;
}
KeSetEvent(&DeviceExtension->InputBufferNotEmpty, 0, FALSE);
KeReleaseSpinLock(&DeviceExtension->InputBufferLock, Irql);
/* allow new interrupts */
IER = READ_PORT_UCHAR(SER_IER(ComPortBase));
WRITE_PORT_UCHAR(SER_IER(ComPortBase), IER | SR_IER_DATA_RECEIVED);
}
BOOLEAN NTAPI
SerialInterruptService(
IN PKINTERRUPT Interrupt,
IN OUT PVOID ServiceContext)
{
PDEVICE_OBJECT DeviceObject;
PSERIAL_DEVICE_EXTENSION DeviceExtension;
PUCHAR ComPortBase;
UCHAR Iir;
ULONG Events = 0;
BOOLEAN ret = FALSE;
/* FIXME: sometimes, produce SERIAL_EV_RXFLAG event */
DeviceObject = (PDEVICE_OBJECT)ServiceContext;
DeviceExtension = (PSERIAL_DEVICE_EXTENSION)DeviceObject->DeviceExtension;
ComPortBase = ULongToPtr(DeviceExtension->BaseAddress);
Iir = READ_PORT_UCHAR(SER_IIR(ComPortBase));
if (Iir == 0xff)
return TRUE;
Iir &= SR_IIR_ID_MASK;
if ((Iir & SR_IIR_SELF) != 0) { return FALSE; }
switch (Iir)
{
case SR_IIR_MSR_CHANGE:
{
UCHAR MSR, IER;
TRACE_(SERIAL, "SR_IIR_MSR_CHANGE\n");
MSR = READ_PORT_UCHAR(SER_MSR(ComPortBase));
if (MSR & SR_MSR_CTS_CHANGED)
{
if (MSR & SR_MSR_CTS)
KeInsertQueueDpc(&DeviceExtension->SendByteDpc, NULL, NULL);
else
{
; /* FIXME: stop transmission */
}
Events |= SERIAL_EV_CTS;
}
if (MSR & SR_MSR_DSR_CHANGED)
{
if (MSR & SR_MSR_DSR)
KeInsertQueueDpc(&DeviceExtension->ReceivedByteDpc, NULL, NULL);
else
{
; /* FIXME: stop reception */
}
Events |= SERIAL_EV_DSR;
}
if (MSR & SR_MSR_RI_CHANGED)
{
INFO_(SERIAL, "SR_MSR_RI_CHANGED changed: now %d\n", MSR & SI_MSR_RI);
Events |= SERIAL_EV_RING;
}
if (MSR & SR_MSR_DCD_CHANGED)
{
INFO_(SERIAL, "SR_MSR_DCD_CHANGED changed: now %d\n", MSR & SR_MSR_DCD);
Events |= SERIAL_EV_RLSD;
}
IER = READ_PORT_UCHAR(SER_IER(ComPortBase));
WRITE_PORT_UCHAR(SER_IER(ComPortBase), IER | SR_IER_MSR_CHANGE);
ret = TRUE;
goto done;
}
case SR_IIR_THR_EMPTY:
{
TRACE_(SERIAL, "SR_IIR_THR_EMPTY\n");
KeInsertQueueDpc(&DeviceExtension->SendByteDpc, NULL, NULL);
Events |= SERIAL_EV_TXEMPTY;
ret = TRUE;
goto done;
}
case SR_IIR_DATA_RECEIVED:
{
ULONG AlreadyReceivedBytes, Limit;
TRACE_(SERIAL, "SR_IIR_DATA_RECEIVED\n");
KeInsertQueueDpc(&DeviceExtension->ReceivedByteDpc, NULL, NULL);
Events |= SERIAL_EV_RXCHAR;
/* Check if buffer will be 80% full */
AlreadyReceivedBytes = GetNumberOfElementsInCircularBuffer(
&DeviceExtension->InputBuffer) * 5;
Limit = DeviceExtension->InputBuffer.Length * 4;
if (AlreadyReceivedBytes < Limit && AlreadyReceivedBytes + 1 >= Limit)
{
/* Buffer is full at 80% */
Events |= SERIAL_EV_RX80FULL;
}
ret = TRUE;
goto done;
}
case SR_IIR_ERROR:
{
UCHAR LSR;
TRACE_(SERIAL, "SR_IIR_ERROR\n");
LSR = READ_PORT_UCHAR(SER_LSR(ComPortBase));
if (LSR & SR_LSR_OVERRUN_ERROR)
{
InterlockedIncrement((PLONG)&DeviceExtension->SerialPerfStats.SerialOverrunErrorCount);
Events |= SERIAL_EV_ERR;
}
if (LSR & SR_LSR_PARITY_ERROR)
{
InterlockedIncrement((PLONG)&DeviceExtension->SerialPerfStats.ParityErrorCount);
Events |= SERIAL_EV_ERR;
}
if (LSR & SR_LSR_FRAMING_ERROR)
{
InterlockedIncrement((PLONG)&DeviceExtension->SerialPerfStats.FrameErrorCount);
Events |= SERIAL_EV_ERR;
}
if (LSR & SR_LSR_BREAK_INT)
{
InterlockedIncrement((PLONG)&DeviceExtension->BreakInterruptErrorCount);
Events |= SERIAL_EV_BREAK;
}
ret = TRUE;
goto done;
}
}
done:
if (!ret)
return FALSE;
if (DeviceExtension->WaitOnMaskIrp && (Events & DeviceExtension->WaitMask))
{
/* Finish pending IRP */
PULONG pEvents = (PULONG)DeviceExtension->WaitOnMaskIrp->AssociatedIrp.SystemBuffer;
DeviceExtension->WaitOnMaskIrp->IoStatus.Status = STATUS_SUCCESS;
DeviceExtension->WaitOnMaskIrp->IoStatus.Information = sizeof(ULONG);
*pEvents = Events;
KeInsertQueueDpc(&DeviceExtension->CompleteIrpDpc, DeviceExtension->WaitOnMaskIrp, NULL);
/* We are now ready to handle another IRP, even if this one is not completed */
DeviceExtension->WaitOnMaskIrp = NULL;
return STATUS_SUCCESS;
}
return TRUE;
}
UART_TYPE
SerialDetectUartType(
IN PUCHAR BaseAddress)
{
UCHAR Lcr, TestLcr;
UCHAR OldScr, Scr5A, ScrA5;
BOOLEAN FifoEnabled;
UCHAR NewFifoStatus;
Lcr = READ_PORT_UCHAR(SER_LCR(BaseAddress));
WRITE_PORT_UCHAR(SER_LCR(BaseAddress), Lcr ^ 0xFF);
TestLcr = READ_PORT_UCHAR(SER_LCR(BaseAddress)) ^ 0xFF;
WRITE_PORT_UCHAR(SER_LCR(BaseAddress), Lcr);
/* Accessing the LCR must work for a usable serial port */
if (TestLcr != Lcr)
return UartUnknown;
/* Ensure that all following accesses are done as required */
READ_PORT_UCHAR(SER_RBR(BaseAddress));
READ_PORT_UCHAR(SER_IER(BaseAddress));
READ_PORT_UCHAR(SER_IIR(BaseAddress));
READ_PORT_UCHAR(SER_LCR(BaseAddress));
READ_PORT_UCHAR(SER_MCR(BaseAddress));
READ_PORT_UCHAR(SER_LSR(BaseAddress));
READ_PORT_UCHAR(SER_MSR(BaseAddress));
READ_PORT_UCHAR(SER_SCR(BaseAddress));
/* Test scratch pad */
OldScr = READ_PORT_UCHAR(SER_SCR(BaseAddress));
WRITE_PORT_UCHAR(SER_SCR(BaseAddress), 0x5A);
Scr5A = READ_PORT_UCHAR(SER_SCR(BaseAddress));
WRITE_PORT_UCHAR(SER_SCR(BaseAddress), 0xA5);
ScrA5 = READ_PORT_UCHAR(SER_SCR(BaseAddress));
WRITE_PORT_UCHAR(SER_SCR(BaseAddress), OldScr);
/* When non-functional, we have a 8250 */
if (Scr5A != 0x5A || ScrA5 != 0xA5)
return Uart8250;
/* Test FIFO type */
FifoEnabled = (READ_PORT_UCHAR(SER_IIR(BaseAddress)) & 0x80) != 0;
WRITE_PORT_UCHAR(SER_FCR(BaseAddress), SR_FCR_ENABLE_FIFO);
NewFifoStatus = READ_PORT_UCHAR(SER_IIR(BaseAddress)) & 0xC0;
if (!FifoEnabled)
WRITE_PORT_UCHAR(SER_FCR(BaseAddress), 0);
switch (NewFifoStatus)
{
case 0x00:
return Uart16450;
case 0x40:
case 0x80:
/* Not sure about this but the documentation says that 0x40
* indicates an unusable FIFO but my tests only worked
* with 0x80 */
return Uart16550;
}
/* FIFO is only functional for 16550A+ */
return Uart16550A;
}
