Exemplo n.º 1
0
void
HardwareSerial::primeTransmit(unsigned long ulBase)
{
    //
    // Do we have any data to transmit?
    //
    if(!TX_BUFFER_EMPTY)
    {
        //
        // Disable the UART interrupt. If we don't do this there is a race
        // condition which can cause the read index to be corrupted.
        //
        ROM_IntDisable(g_ulUARTInt[uartModule]);
        //
        // Yes - take some characters out of the transmit buffer and feed
        // them to the UART transmit FIFO.
        //
        while(!TX_BUFFER_EMPTY)
        {
            while(ROM_UARTSpaceAvail(ulBase) && !TX_BUFFER_EMPTY) {
                ROM_UARTCharPutNonBlocking(ulBase,
                                           txBuffer[txReadIndex]);

                txReadIndex = (txReadIndex + 1) % SERIAL_BUFFER_SIZE;
            }
        }

        //
        // Reenable the UART interrupt.
        //
        ROM_IntEnable(g_ulUARTInt[uartModule]);
    }
}
Exemplo n.º 2
0
//*****************************************************************************
// UART interrupt handler.
//*****************************************************************************
void UART0_IntHandler(void)
{
    uint32_t status = ROM_UARTIntStatus(UART0_BASE, true);
    ROM_UARTIntClear(UART0_BASE, status);
    
    // drain rx FIFO
    while(ROM_UARTCharsAvail(UART0_BASE))
    {
        char ch = ROM_UARTCharGetNonBlocking(UART0_BASE);
        
        if(inputRB.nbytes < DBG_IN_BUFFER_SIZE)
        {
            RB_Push(dbg_inputBuffer, inputRB, ch, DBG_IN_BUFFER_SIZE);
            if(ch == '\r')
                ++newlines;
        }
        else
        {
            // Attempt to report overflow and clear buffer
            // Must do this to avoid condition where buffer is full and code
            // is waiting for a newline that can not fit in the buffer.
            dbg_putstr_nb("\rRXOVF\r\n");
            RB_Clear(inputRB);
            newlines = 0;
        }
    }
    
    // feed tx FIFO
    // Echo received characters
    while(ROM_UARTSpaceAvail(UART0_BASE) && echoPtr != inputRB.wp)
    {
        ROM_UARTCharPutNonBlocking(UART0_BASE, dbg_inputBuffer[echoPtr]);
        echoPtr = (echoPtr + 1) % DBG_IN_BUFFER_SIZE;
    }
    // Write pending characters
    while(ROM_UARTSpaceAvail(UART0_BASE) && outputRB.nbytes > 0)
    {
        ROM_UARTCharPutNonBlocking(UART0_BASE, RB_Front(dbg_outputBuffer, outputRB));
        RB_Pop(outputRB, DBG_OUT_BUFFER_SIZE);
    }
} // UART0_IntHandler()
Exemplo n.º 3
0
int dbg_putc_nb(char ch, void * userdata)
{
    if(ROM_UARTSpaceAvail(UART0_BASE) && outputRB.nbytes == 0)
    {
        ROM_UARTCharPutNonBlocking(UART0_BASE, ch);
    }
    else
    {
        if(!RB_Full(outputRB, DBG_OUT_BUFFER_SIZE))
            RB_Push(dbg_outputBuffer, outputRB, ch, DBG_OUT_BUFFER_SIZE);
    }
    return 0;
}
Exemplo n.º 4
0
//*****************************************************************************
//
// Take as many bytes from the transmit buffer as we have space for and move
// them into the USB UART's transmit FIFO.
//
//*****************************************************************************
static void
USBUARTPrimeTransmit(uint32_t ui32Base)
{
    uint32_t ui32Read;
    uint8_t ui8Char;

    //
    // If we are currently sending a break condition, don't receive any
    // more data. We will resume transmission once the break is turned off.
    //
    if(g_bSendingBreak)
    {
        return;
    }

    //
    // If there is space in the UART FIFO, try to read some characters
    // from the receive buffer to fill it again.
    //
    while(ROM_UARTSpaceAvail(ui32Base))
    {
        //
        // Get a character from the buffer.
        //
        ui32Read = USBBufferRead((tUSBBuffer *)&g_sRxBuffer, &ui8Char, 1);

        //
        // Did we get a character?
        //
        if(ui32Read)
        {
            //
            // Place the character in the UART transmit FIFO.
            //
            ROM_UARTCharPutNonBlocking(ui32Base, ui8Char);

            //
            // Update our count of bytes transmitted via the UART.
            //
            g_ui32UARTTxCount++;
        }
        else
        {
            //
            // We ran out of characters so exit the function.
            //
            return;
        }
    }
}
//*****************************************************************************
//
// Take as many bytes from the transmit buffer as there is space for and move
// them into the USB UART's transmit FIFO.
//
//*****************************************************************************
static void
USBUARTPrimeTransmit(void)
{
    unsigned long ulRead;
    unsigned char ucChar;

    //
    // If a break condition is currently being sent, don't receive any more
    // data.  Transmission will resume once the break is turned off.
    //
    if(g_bSendingBreak)
    {
        return;
    }

    //
    // If there is space in the UART FIFO, try to read some characters
    // from the receive buffer to fill it again.
    //
    while(ROM_UARTSpaceAvail(UART0_BASE))
    {
        //
        // Get a character from the buffer.
        //
        ulRead = USBBufferRead(&g_sRxBuffer, &ucChar, 1);

        //
        // Was a character read?
        //
        if(ulRead)
        {
            //
            // Place the character in the UART transmit FIFO.
            //
            ROM_UARTCharPutNonBlocking(UART0_BASE, ucChar);
        }
        else
        {
            //
            // There are no more characters so exit the function.
            //
            return;
        }
    }
}
Exemplo n.º 6
0
//*****************************************************************************
//
// Handles interrupts from the UART.
//
//*****************************************************************************
void
UART0IntHandler(void)
{
    unsigned long ulStatus;
    unsigned char ucChar;

    //
    // Get the interrupts that are being asserted by the UART.
    //
    ulStatus = ROM_UARTIntStatus(UART0_BASE, true);

    //
    // Clear the asserted interrupts.
    //
    ROM_UARTIntClear(UART0_BASE, ulStatus);

    //
    // Indicate that the UART link is good.
    //
    ControllerLinkGood(LINK_TYPE_UART);

    //
    // See if the receive interrupt has been asserted.
    //
    if(ulStatus & (UART_INT_RX | UART_INT_RT))
    {
        //
        // Loop while there are more characters to be read from the UART.
        //
        while(ROM_UARTCharsAvail(UART0_BASE))
        {
            //
            // Read the next character from the UART.
            //
            ucChar = ROM_UARTCharGet(UART0_BASE);

            //
            // See if this is a start of packet byte.
            //
            if(ucChar == 0xff)
            {
                //
                // Reset the length of the UART message.
                //
                g_ulUARTLength = 0;

                //
                // Set the state such that the next byte received is the size
                // of the message.
                //
                g_ulUARTState = UART_STATE_LENGTH;
            }

            //
            // See if this byte is the size of the message.
            //
            else if(g_ulUARTState == UART_STATE_LENGTH)
            {
                //
                // Save the size of the message.
                //
                g_ulUARTSize = ucChar;

                //
                // Subsequent bytes received are the message data.
                //
                g_ulUARTState = UART_STATE_DATA;
            }

            //
            // See if the previous character was an escape character.
            //
            else if(g_ulUARTState == UART_STATE_ESCAPE)
            {
                //
                // See if this 0xfe, the escaped version of 0xff.
                //
                if(ucChar == 0xfe)
                {
                    //
                    // Store a 0xff in the message buffer.
                    //
                    g_pucUARTMessage[g_ulUARTLength++] = 0xff;

                    //
                    // Subsequent bytes received are the message data.
                    //
                    g_ulUARTState = UART_STATE_DATA;
                }

                //
                // Otherwise, see if this is 0xfd, the escaped version of 0xfe.
                //
                else if(ucChar == 0xfd)
                {
                    //
                    // Store a 0xfe in the message buffer.
                    //
                    g_pucUARTMessage[g_ulUARTLength++] = 0xfe;

                    //
                    // Subsequent bytes received are the message data.
                    //
                    g_ulUARTState = UART_STATE_DATA;
                }

                //
                // Otherwise, this is a corrupted sequence.  Set the receiver
                // to idle so this message is dropped, and subsequent data is
                // ignored until another start of packet is received.
                //
                else
                {
                    g_ulUARTState = UART_STATE_IDLE;
                }
            }

            //
            // See if this is a part of the message data.
            //
            else if(g_ulUARTState == UART_STATE_DATA)
            {
                //
                // See if this character is an escape character.
                //
                if(ucChar == 0xfe)
                {
                    //
                    // The next byte is an escaped byte.
                    //
                    g_ulUARTState = UART_STATE_ESCAPE;
                }
                else
                {
                    //
                    // Store this byte in the message buffer.
                    //
                    g_pucUARTMessage[g_ulUARTLength++] = ucChar;
                }
            }

            //
            // See if the entire message has been received but has not been
            // processed (i.e. the most recent byte received was the end of the
            // message).
            //
            if((g_ulUARTLength == g_ulUARTSize) &&
               (g_ulUARTState == UART_STATE_DATA))
            {
                //
                // Process this message.
                //
                UARTIFCommandHandler();

                //
                // The UART interface is idle, meaning all bytes will be
                // dropped until the next start of packet byte.
                //
                g_ulUARTState = UART_STATE_IDLE;
            }
        }

        //
        // Tell the controller that CAN activity was detected.
        //
        ControllerWatchdog(LINK_TYPE_UART);
    }

    //
    // See if the transmit interrupt has been asserted.
    //
    if(ulStatus & UART_INT_TX)
    {
        //
        // Loop while there are more characters to be transmitted and more
        // space in the UART FIFO.
        //
        while((g_ulUARTXmitRead != g_ulUARTXmitWrite) &&
              ROM_UARTSpaceAvail(UART0_BASE))
        {
            //
            // Put the next character into the UART FIFO.
            //
            ROM_UARTCharPut(UART0_BASE, g_pucUARTXmit[g_ulUARTXmitRead]);

            //
            // Increment the read pointer.
            //
            g_ulUARTXmitRead = (g_ulUARTXmitRead + 1) % UART_XMIT_SIZE;
        }
    }

    //
    // See if an enumeration response needs to be sent.
    //
    if(HWREGBITW(&g_ulUARTFlags, UART_FLAG_ENUM) != 0)
    {
        //
        // Send the enumeration response for this device.
        //
        UARTIFSendMessage(CAN_MSGID_API_ENUMERATE |
                          g_sParameters.ucDeviceNumber, 0, 0);

        //
        // Clear the enumeration response flag.
        //
        HWREGBITW(&g_ulUARTFlags, UART_FLAG_ENUM) = 0;
    }

    //
    // See if periodic status messages need to be sent.
    //
    if(HWREGBITW(&g_ulUARTFlags, UART_FLAG_PSTATUS) != 0)
    {
        //
        // Send out the first periodic status message if it needs to be sent.
        //
        if(g_ulPStatFlags & 1)
        {
            UARTIFSendMessage(LM_API_PSTAT_DATA_S0 |
                              g_sParameters.ucDeviceNumber,
                              g_ppucPStatMessages[0],
                              g_pucPStatMessageLen[0]);
        }

        //
        // Send out the second periodic status message if it needs to be sent.
        //
        if(g_ulPStatFlags & 2)
        {
            UARTIFSendMessage(LM_API_PSTAT_DATA_S1 |
                              g_sParameters.ucDeviceNumber,
                              g_ppucPStatMessages[1],
                              g_pucPStatMessageLen[1]);
        }

        //
        // Send out the third periodic status message if it needs to be sent.
        //
        if(g_ulPStatFlags & 4)
        {
            UARTIFSendMessage(LM_API_PSTAT_DATA_S2 |
                              g_sParameters.ucDeviceNumber,
                              g_ppucPStatMessages[2],
                              g_pucPStatMessageLen[2]);
        }

        //
        // Send out the fourth periodic status message if it needs to be sent.
        //
        if(g_ulPStatFlags & 8)
        {
            UARTIFSendMessage(LM_API_PSTAT_DATA_S3 |
                              g_sParameters.ucDeviceNumber,
                              g_ppucPStatMessages[3],
                              g_pucPStatMessageLen[3]);
        }

        //
        // Clear the periodic status message flag.
        //
        HWREGBITW(&g_ulUARTFlags, UART_FLAG_PSTATUS) = 0;
    }
}
Exemplo n.º 7
0
//*****************************************************************************
//
// Sends a character to the UART.
//
//*****************************************************************************
static void
UARTIFPutChar(unsigned long ulChar)
{
    //
    // See if the character being sent is 0xff.
    //
    if(ulChar == 0xff)
    {
        //
        // Send 0xfe 0xfe, the escaped version of 0xff.  A sign extended
        // version of 0xfe is used to avoid the check below for 0xfe, thereby
        // avoiding an infinite loop.  Only the lower 8 bits are actually sent,
        // so 0xfe is what is actually transmitted.
        //
        UARTIFPutChar(0xfffffffe);
        UARTIFPutChar(0xfffffffe);
    }

    //
    // Otherwise, see if the character being sent is 0xfe.
    //
    else if(ulChar == 0xfe)
    {
        //
        // Send 0xfe 0xfd, the escaped version of 0xfe.  A sign extended
        // version of 0xfe is used to avoid the check above for 0xfe, thereby
        // avoiding an infinite loop.  Only the lower 8 bits are actually sent,
        // so 0xfe is what is actually transmitted.
        //
        UARTIFPutChar(0xfffffffe);
        UARTIFPutChar(0xfd);
    }

    //
    // Otherwise, simply send this character.
    //
    else
    {
        //
        // Disable the UART interrupt to avoid having characters stick in the
        // local buffer.
        //
        ROM_UARTIntDisable(UART0_BASE, UART_INT_TX);

        //
        // See if the local buffer is empty and there is space available in the
        // UART FIFO.
        //
        if((g_ulUARTXmitRead == g_ulUARTXmitWrite) &&
           ROM_UARTSpaceAvail(UART0_BASE))
        {
            //
            // Simply write this character into the UART FIFO.
            //
            ROM_UARTCharPut(UART0_BASE, ulChar);
        }
        else
        {
            //
            // Write this character into the local buffer.
            //
            g_pucUARTXmit[g_ulUARTXmitWrite] = ulChar;

            //
            // Increment the local write buffer pointer.
            //
            g_ulUARTXmitWrite = (g_ulUARTXmitWrite + 1) % UART_XMIT_SIZE;
        }

        //
        // Re-enable the UART interrupt.
        //
        ROM_UARTIntEnable(UART0_BASE, UART_INT_TX);
    }
}