//#pragma comment(exestr, "$Header: /usr4/winnt/SOURCES/halpcims/src/hal/halsnipm/mips/RCS/jxport.c,v 1.1 1995/07/20 15:58:02 flo Exp $") /*++ Copyright (c) 1991-1994 Microsoft Corporation Module Name: jxport.c Abstract: This module implements the code that provides communication between the kernel debugger on a MIPS R4000 system and the host system. Environment: Kernel mode Revision History: --*/ #include "halp.h" #include "jazzserp.h" // set the correct divisor for the SNI serial ports / quartz clock #if defined(SNI) #undef BAUD_RATE_9600 #undef BAUD_RATE_19200 #define BAUD_RATE_9600 12 #define BAUD_RATE_19200 6 #endif // SNI #define HEADER_FILE #include "kxmips.h" VOID HalpGetDivisorFromBaud( IN ULONG ClockRate, IN LONG DesiredBaud, OUT PSHORT AppropriateDivisor ); #pragma alloc_text(INIT,HalpGetDivisorFromBaud) // // BUGBUG Temporarily, we use counter to do the timeout // #define TIMEOUT_COUNT 1024*512 // // BUGBUG Temp until we have a configuration manager. // PUCHAR KdComPortInUse = NULL; BOOLEAN KdUseModemControl = FALSE; // // Define serial port read and write addresses. // #if defined(USE_COM2) // Assume COM2 for the kernel debugger. #define SP_READ ((PSP_READ_REGISTERS) ((ULONG)HalpOnboardControlBase + SERIAL1_RELATIVE_BASE)) #define SP_WRITE ((PSP_WRITE_REGISTERS)((ULONG)HalpOnboardControlBase + SERIAL1_RELATIVE_BASE)) #else // Assume COM1 for the kernel debugger. #define SP_READ ((PSP_READ_REGISTERS) ((ULONG)HalpOnboardControlBase + SERIAL0_RELATIVE_BASE)) #define SP_WRITE ((PSP_WRITE_REGISTERS)((ULONG)HalpOnboardControlBase + SERIAL0_RELATIVE_BASE)) #endif // // Define forward referenced prototypes. // SP_LINE_STATUS KdReadLsr ( IN BOOLEAN WaitReason ); // // Define baud rate divisor to be used on the debugger port. // SHORT HalpBaudRateDivisor = BAUD_RATE_19200; ULONG HalpGetByte ( IN PCHAR Input, IN BOOLEAN Wait ) /*++ Routine Description: This routine gets a byte from the serial port used by the kernel debugger. Arguments: Input - Supplies a pointer to a variable that receives the input data byte. Wait - Supplies a boolean value that detemines whether a timeout is applied to the input operation. Return Value: CP_GET_SUCCESS is returned if a byte is successfully read from the kernel debugger line. CP_GET_ERROR is returned if an error is encountered during reading. CP_GET_NODATA is returned if timeout occurs. --*/ { SP_LINE_STATUS LsrByte; UCHAR DataByte; ULONG TimeoutCount; // // Attempt to read a byte from the debugger port until a byte is // available or until a timeout occurs. // TimeoutCount = Wait ? TIMEOUT_COUNT : 1; do { TimeoutCount -= 1; // // Wait until data is available in the receive buffer. // KeStallExecutionProcessor(1); LsrByte = KdReadLsr(TRUE); if (LsrByte.DataReady == 0) { continue; } // // Read input byte and store in callers buffer. // *Input = READ_REGISTER_UCHAR(&SP_READ->ReceiveBuffer); // // If using modem controls, then skip any incoming data while // ReceiveData not set. // if (KdUseModemControl) { DataByte = READ_REGISTER_UCHAR(&SP_READ->ModemStatus); if ( ((PSP_MODEM_STATUS)&DataByte)->ReceiveDetect == 0) { continue; } } // // Return function value as the not of the error indicators. // if (LsrByte.ParityError || LsrByte.FramingError || LsrByte.OverrunError || LsrByte.BreakIndicator) { return CP_GET_ERROR; } return CP_GET_SUCCESS; } while(TimeoutCount != 0); return CP_GET_NODATA; } BOOLEAN KdPortInitialize ( PDEBUG_PARAMETERS DebugParameters, PLOADER_PARAMETER_BLOCK LoaderBlock, BOOLEAN Initialize ) /*++ Routine Description: This routine initializes the serial port used by the kernel debugger and must be called during system initialization. Arguments: DebugParameter - Supplies a pointer to the debug port parameters. LoaderBlock - Supplies a pointer to the loader parameter block. Initialize - Specifies a boolean value that determines whether the debug port is initialized or just the debug port parameters are captured. Return Value: A value of TRUE is returned is the port was successfully initialized. Otherwise, a value of FALSE is returned. --*/ { PCONFIGURATION_COMPONENT_DATA ConfigurationEntry; UCHAR DataByte; PCM_PARTIAL_RESOURCE_DESCRIPTOR Descriptor; PCM_SERIAL_DEVICE_DATA DeviceData; PCM_PARTIAL_RESOURCE_LIST List; ULONG MatchKey; ULONG BaudRate; ULONG BaudClock; // // Find the configuration information for the first serial port. // if (LoaderBlock != NULL) { MatchKey = 0; ConfigurationEntry = KeFindConfigurationEntry(LoaderBlock->ConfigurationRoot, ControllerClass, SerialController, &MatchKey); } else { ConfigurationEntry = NULL; } if (DebugParameters->BaudRate != 0) { BaudRate = DebugParameters->BaudRate; } else { BaudRate = 19200; } // // If the serial configuration entry was not found or the frequency // specified is not supported, then default the baud clock to 800000. // BaudClock = 8000000; if (ConfigurationEntry != NULL) { List = (PCM_PARTIAL_RESOURCE_LIST)ConfigurationEntry->ConfigurationData; Descriptor = &List->PartialDescriptors[List->Count]; DeviceData = (PCM_SERIAL_DEVICE_DATA)Descriptor; if ((DeviceData->BaudClock == 1843200) || (DeviceData->BaudClock == 4233600) || (DeviceData->BaudClock == 8000000)) { BaudClock = DeviceData->BaudClock; } } HalpGetDivisorFromBaud( BaudClock, BaudRate, &HalpBaudRateDivisor ); // // If the debugger is not being enabled, then return. // if (Initialize == FALSE) { return TRUE; } // // BUGBUG the FW configuration sets the serial 0 Port config relativ to // the EISA/ISA Base Address, so the serial driver doesn't get the right // information when debugging is enabled .... // #if defined(USE_COM2) KdComPortInUse=(PUCHAR)(SERIAL1_PHYSICAL_BASE); #else KdComPortInUse=(PUCHAR)(SERIAL0_PHYSICAL_BASE); #endif // // Clear the divisor latch, clear all interrupt enables, and reset and // disable the FIFO's. // WRITE_REGISTER_UCHAR(&SP_WRITE->LineControl, 0x0); WRITE_REGISTER_UCHAR(&SP_WRITE->InterruptEnable, 0x0); DataByte = 0; ((PSP_FIFO_CONTROL)(&DataByte))->ReceiveFifoReset = 1; ((PSP_FIFO_CONTROL)(&DataByte))->TransmitFifoReset = 1; WRITE_REGISTER_UCHAR(&SP_WRITE->FifoControl, DataByte); // // Set the divisor latch and set the baud rate. // ((PSP_LINE_CONTROL)(&DataByte))->DivisorLatch = 1; WRITE_REGISTER_UCHAR(&SP_WRITE->LineControl, DataByte); WRITE_REGISTER_UCHAR(&SP_WRITE->TransmitBuffer,(UCHAR)(HalpBaudRateDivisor&0xFF)); WRITE_REGISTER_UCHAR(&SP_WRITE->InterruptEnable,(UCHAR)(HalpBaudRateDivisor>>8)); // // Clear the divisor latch and set the character size to eight bits // with one stop bit and no parity checking. // DataByte = 0; ((PSP_LINE_CONTROL)(&DataByte))->CharacterSize = EIGHT_BITS; WRITE_REGISTER_UCHAR(&SP_WRITE->LineControl, DataByte); // // Set data terminal ready and request to send. // DataByte = 0; ((PSP_MODEM_CONTROL)(&DataByte))->DataTerminalReady = 1; ((PSP_MODEM_CONTROL)(&DataByte))->RequestToSend = 1; WRITE_REGISTER_UCHAR(&SP_WRITE->ModemControl, DataByte); return TRUE; } ULONG KdPortGetByte ( OUT PUCHAR Input ) /*++ Routine Description: This routine gets a byte from the serial port used by the kernel debugger. N.B. It is assumed that the IRQL has been raised to the highest level, and necessary multiprocessor synchronization has been performed before this routine is called. Arguments: Input - Supplies a pointer to a variable that receives the input data byte. Return Value: CP_GET_SUCCESS is returned if a byte is successfully read from the kernel debugger line. CP_GET_ERROR is returned if an error is encountered during reading. CP_GET_NODATA is returned if timeout occurs. --*/ { return HalpGetByte(Input, TRUE); } ULONG KdPortPollByte ( OUT PUCHAR Input ) /*++ Routine Description: This routine gets a byte from the serial port used by the kernel debugger iff a byte is available. N.B. It is assumed that the IRQL has been raised to the highest level, and necessary multiprocessor synchronization has been performed before this routine is called. Arguments: Input - Supplies a pointer to a variable that receives the input data byte. Return Value: CP_GET_SUCCESS is returned if a byte is successfully read from the kernel debugger line. CP_GET_ERROR is returned if an error encountered during reading. CP_GET_NODATA is returned if timeout occurs. --*/ { ULONG Status; // // Save port status, map the serial controller, get byte from the // debugger port is one is avaliable, restore port status, unmap // the serial controller, and return the operation status. // KdPortSave(); Status = HalpGetByte(Input, FALSE); KdPortRestore(); return Status; } VOID KdPortPutByte ( IN UCHAR Output ) /*++ Routine Description: This routine puts a byte to the serial port used by the kernel debugger. N.B. It is assumed that the IRQL has been raised to the highest level, and necessary multiprocessor synchronization has been performed before this routine is called. Arguments: Output - Supplies the output data byte. Return Value: None. --*/ { UCHAR DataByte; if (KdUseModemControl) { // // Modem control, make sure DSR, CTS and CD are all set before // sending any data. // for (; ;) { DataByte = READ_REGISTER_UCHAR(&SP_READ->ModemStatus); if ( ((PSP_MODEM_STATUS)&DataByte)->ClearToSend && ((PSP_MODEM_STATUS)&DataByte)->DataSetReady && ((PSP_MODEM_STATUS)&DataByte)->ReceiveDetect ) { break; } KdReadLsr(FALSE); } } // // Wait for transmit ready. // while (KdReadLsr(FALSE).TransmitHoldingEmpty == 0 ); // // Wait for data set ready. // // do { // LsrByte = READ_REGISTER_UCHAR(&SP_READ->ModemStatus); // } while (((PSP_MODEM_STATUS)(&LsrByte))->DataSetReady == 0); // // Transmit data. // WRITE_REGISTER_UCHAR(&SP_WRITE->TransmitBuffer, Output); return; } VOID KdPortRestore ( VOID ) /*++ Routine Description: This routine restores the state of the serial port after the kernel debugger has been active. N.B. This routine performs no function on the Jazz system. Arguments: None. Return Value: None. --*/ { return; } VOID KdPortSave ( VOID ) /*++ Routine Description: This routine saves the state of the serial port and initializes the port for use by the kernel debugger. N.B. This routine performs no function on the Jazz system. Arguments: None. Return Value: None. --*/ { return; } SP_LINE_STATUS KdReadLsr ( IN BOOLEAN WaitReason ) /*++ Routine Description: Returns current line status. If status which is being waited for is ready, then the function checks the current modem status and causes a possible display update of the current statuses. Arguments: WaitReason - Suuplies a boolean value that determines whether the line status is required for a receive or transmit. Return Value: The current line status is returned as the function value. --*/ { static UCHAR RingFlag = 0; UCHAR DataLsr, DataMsr; // // Get the line status for a recevie or a transmit. // DataLsr = READ_REGISTER_UCHAR(&SP_READ->LineStatus); if (WaitReason) { // // Get line status for receive data. // if (((PSP_LINE_STATUS)&DataLsr)->DataReady) { return *((PSP_LINE_STATUS)&DataLsr); } } else { // // Get line status for transmit empty. // if (((PSP_LINE_STATUS)&DataLsr)->TransmitEmpty) { return *((PSP_LINE_STATUS)&DataLsr); } } DataMsr = READ_REGISTER_UCHAR(&SP_READ->ModemStatus); RingFlag |= ((PSP_MODEM_STATUS)&DataMsr)->RingIndicator ? 1 : 2; if (RingFlag == 3) { // // The ring indicate line has toggled, use modem control from // now on. // KdUseModemControl = TRUE; } return *((PSP_LINE_STATUS) &DataLsr); } VOID HalpGetDivisorFromBaud( IN ULONG ClockRate, IN LONG DesiredBaud, OUT PSHORT AppropriateDivisor ) /*++ Routine Description: This routine will determine a divisor based on an unvalidated baud rate. Arguments: ClockRate - The clock input to the controller. DesiredBaud - The baud rate for whose divisor we seek. AppropriateDivisor - Given that the DesiredBaud is valid, the SHORT pointed to by this parameter will be set to the appropriate value. If the requested baud rate is unsupportable on the machine return a divisor appropriate for 19200. Return Value: none. --*/ { SHORT calculatedDivisor; ULONG denominator; ULONG remainder; // // Allow up to a 1 percent error // ULONG maxRemain18 = 18432; ULONG maxRemain30 = 30720; ULONG maxRemain42 = 42336; ULONG maxRemain80 = 80000; ULONG maxRemain; // // Reject any non-positive bauds. // denominator = DesiredBaud*(ULONG)16; if (DesiredBaud <= 0) { *AppropriateDivisor = -1; } else if ((LONG)denominator < DesiredBaud) { // // If the desired baud was so huge that it cause the denominator // calculation to wrap, don't support it. // *AppropriateDivisor = -1; } else { if (ClockRate == 1843200) { maxRemain = maxRemain18; } else if (ClockRate == 3072000) { maxRemain = maxRemain30; } else if (ClockRate == 4233600) { maxRemain = maxRemain42; } else { maxRemain = maxRemain80; } calculatedDivisor = (SHORT)(ClockRate / denominator); remainder = ClockRate % denominator; // // Round up. // if (((remainder*2) > ClockRate) && (DesiredBaud != 110)) { calculatedDivisor++; } // // Only let the remainder calculations effect us if // the baud rate is > 9600. // if (DesiredBaud >= 9600) { // // If the remainder is less than the maximum remainder (wrt // the ClockRate) or the remainder + the maximum remainder is // greater than or equal to the ClockRate then assume that the // baud is ok. // if ((remainder >= maxRemain) && ((remainder+maxRemain) < ClockRate)) { calculatedDivisor = -1; } } // // Don't support a baud that causes the denominator to // be larger than the clock. // if (denominator > ClockRate) { calculatedDivisor = -1; } // // Ok, Now do some special casing so that things can actually continue // working on all platforms. // if (ClockRate == 1843200) { if (DesiredBaud == 56000) { calculatedDivisor = 2; } } else if (ClockRate == 3072000) { if (DesiredBaud == 14400) { calculatedDivisor = 13; } } else if (ClockRate == 4233600) { if (DesiredBaud == 9600) { calculatedDivisor = 28; } else if (DesiredBaud == 14400) { calculatedDivisor = 18; } else if (DesiredBaud == 19200) { calculatedDivisor = 14; } else if (DesiredBaud == 38400) { calculatedDivisor = 7; } else if (DesiredBaud == 56000) { calculatedDivisor = 5; } } else if (ClockRate == 8000000) { if (DesiredBaud == 14400) { calculatedDivisor = 35; } else if (DesiredBaud == 56000) { calculatedDivisor = 9; } } *AppropriateDivisor = calculatedDivisor; } if (*AppropriateDivisor == -1) { HalpGetDivisorFromBaud( ClockRate, 19200, AppropriateDivisor ); } }