study_serial.c

基于ARM S3C44B0X的ECOS 硬件移植代码

  study_serial_info *study_chan = (study_serial_info *)chan->dev_priv;
  volatile struct serial_port *port = (volatile struct serial_port *)study_chan->base;
  cyg_uint32 word_length = select_word_length[(new_config->word_length)-CYGNUM_SERIAL_WORD_LENGTH_5];
  cyg_uint32 stop_bits = select_stop_bits[(new_config->stop)-CYGNUM_SERIAL_STOP_1];
  cyg_uint32 parity_mode = select_parity[(new_config->parity)-CYGNUM_SERIAL_PARITY_NONE];
  cyg_uint32 baud_divisor = select_baud[(new_config->baud)-CYGNUM_SERIAL_BAUD_50];
  cyg_uint32 res = word_length | stop_bits | parity_mode | ULCON_IROFF;
  if ((word_length|stop_bits|parity_mode|baud_divisor) == U_NOT_SUPP) {
    return false;
  };
  port->REG_ULCON = res;
  port->REG_UCON = UCON_RXMINT | UCON_RXSIOFF | UCON_TXMINT | UCON_SBKOFF | UCON_LPBOFF;
  port->REG_UBRDIV = baud_divisor;
  if (new_config != &chan->config) {
    chan->config = *new_config;
  };
  return true;
}

// Function to initialize the device.  Called at bootstrap time.
static bool 
study_serial_init(struct cyg_devtab_entry *tab)
{
    serial_channel *chan = (serial_channel *)tab->priv;
    study_serial_info *study_chan = (study_serial_info *)chan->dev_priv;
#ifdef CYGDBG_IO_INIT
    diag_printf("study SERIAL init - dev: %x.%d.%d\n", study_chan->base, study_chan->tx_int_num, study_chan->rx_int_num);
#endif
    (chan->callbacks->serial_init)(chan);  // Really only required for interrupt driven devices
    if (chan->out_cbuf.len != 0) {         // If bufferlength > 0 then interrupts are used for tx
        cyg_drv_interrupt_create(study_chan->tx_int_num,
                                 99,                     // Priority - unused
                                 (cyg_addrword_t)chan,   //  Data item passed to interrupt handler
                                 study_serial_tx_ISR,
                                 study_serial_tx_DSR,
                                 &study_chan->serial_tx_interrupt_handle,
                                 &study_chan->serial_tx_interrupt);
        cyg_drv_interrupt_attach(study_chan->serial_tx_interrupt_handle);
        cyg_drv_interrupt_mask(study_chan->tx_int_num);
        study_chan->tx_enabled = false;
    }
    if (chan->in_cbuf.len != 0) {         // If bufferlength > 0 then interrupts are used for rx
        cyg_drv_interrupt_create(study_chan->rx_int_num,
                                 99,                     // Priority - unused
                                 (cyg_addrword_t)chan,   //  Data item passed to interrupt handler
                                 study_serial_rx_ISR,
                                 study_serial_rx_DSR,
                                 &study_chan->serial_rx_interrupt_handle,
                                 &study_chan->serial_rx_interrupt);
        cyg_drv_interrupt_attach(study_chan->serial_rx_interrupt_handle);
        cyg_drv_interrupt_unmask(study_chan->rx_int_num);
    }
    study_serial_config_port(chan, &chan->config, true);
    return true;
}

// This routine is called when the device is "looked" up (i.e. attached)
static Cyg_ErrNo 
study_serial_lookup(struct cyg_devtab_entry **tab, 
                  struct cyg_devtab_entry *sub_tab,
                  const char *name)
{
    serial_channel *chan = (serial_channel *)(*tab)->priv;
    (chan->callbacks->serial_init)(chan);  // Really only required for interrupt driven devices
    return ENOERR;
}

// Send a character to the device output buffer.
// Return 'true' if character is sent to device
static bool
study_serial_putc(serial_channel *chan, unsigned char c)
{
    study_serial_info *study_chan = (study_serial_info *)chan->dev_priv;
    volatile struct serial_port *port = (volatile struct serial_port *)study_chan->base;

    if (port->REG_USTAT & USTAT_TBE) {
      // Transmit buffer is empty
      port->REG_UTXBUF = c;
      return true;
    } else {
      // No space
      return false;
    }
}

// Fetch a character from the device input buffer, waiting if necessary
static unsigned char 
study_serial_getc(serial_channel *chan)
{
    unsigned char c;
    study_serial_info *study_chan = (study_serial_info *)chan->dev_priv;
    volatile struct serial_port *port = (volatile struct serial_port *)study_chan->base;
    while ((port->REG_USTAT & USTAT_RDR) == 0) ;   // Wait for char
    c = port->REG_URXBUF;
    return c;
}

// Set up the device characteristics; baud rate, etc.
static Cyg_ErrNo
study_serial_set_config(serial_channel *chan, cyg_uint32 key,
                      const void *xbuf, cyg_uint32 *len)
{
    switch (key) {
    case CYG_IO_SET_CONFIG_SERIAL_INFO:
      {
        cyg_serial_info_t *config = (cyg_serial_info_t *)xbuf;
        if ( *len < sizeof(cyg_serial_info_t) ) {
            return -EINVAL;
        }
        *len = sizeof(cyg_serial_info_t);
        if ( true != study_serial_config_port(chan, config, false) )
            return -EINVAL;
      }
      break;
    default:
        return -EINVAL;
    }
    return ENOERR;
}

// Enable the transmitter on the device
static void
study_serial_start_xmit(serial_channel *chan)
{
    study_serial_info *study_chan = (study_serial_info *)chan->dev_priv;
    study_chan->tx_enabled = true;
    cyg_drv_interrupt_unmask(study_chan->tx_int_num);
}

// Disable the transmitter on the device
static void 
study_serial_stop_xmit(serial_channel *chan)
{
    study_serial_info *study_chan = (study_serial_info *)chan->dev_priv;
    cyg_drv_interrupt_mask(study_chan->tx_int_num);
    study_chan->tx_enabled = false;
}

// Serial I/O - low level tx interrupt handler (ISR)
static cyg_uint32 
study_serial_tx_ISR(cyg_vector_t vector, cyg_addrword_t data)
{
    serial_channel *chan = (serial_channel *)data;
    study_serial_info *study_chan = (study_serial_info *)chan->dev_priv;
    cyg_drv_interrupt_mask(study_chan->tx_int_num);
    cyg_drv_interrupt_acknowledge(study_chan->tx_int_num);
    return CYG_ISR_CALL_DSR;  // Cause DSR to be run
}

// Serial I/O - high level tx interrupt handler (DSR)
static void       
study_serial_tx_DSR(cyg_vector_t vector, cyg_ucount32 count, cyg_addrword_t data)
{
    serial_channel *chan = (serial_channel *)data;
    study_serial_info *study_chan = (study_serial_info *)chan->dev_priv;
    (chan->callbacks->xmt_char)(chan);
    if (study_chan->tx_enabled) {
        cyg_drv_interrupt_unmask(study_chan->tx_int_num);
    }
}

// Serial I/O - low level rx interrupt handler (ISR)
static cyg_uint32 
study_serial_rx_ISR(cyg_vector_t vector, cyg_addrword_t data)
{
    serial_channel *chan = (serial_channel *)data;
    study_serial_info *study_chan = (study_serial_info *)chan->dev_priv;
    cyg_drv_interrupt_mask(study_chan->rx_int_num);
    cyg_drv_interrupt_acknowledge(study_chan->rx_int_num);
    return CYG_ISR_CALL_DSR;  // Cause DSR to be run
}

// Serial I/O - high level rx interrupt handler (DSR)
static void       
study_serial_rx_DSR(cyg_vector_t vector, cyg_ucount32 count, cyg_addrword_t data)
{
    serial_channel *chan = (serial_channel *)data;
    study_serial_info *study_chan = (study_serial_info *)chan->dev_priv;
    volatile struct serial_port *port = (volatile struct serial_port *)study_chan->base;
    (chan->callbacks->rcv_char)(chan, port->REG_URXBUF);
    cyg_drv_interrupt_unmask(study_chan->rx_int_num);
}

#endif // CYGPKG_IO_SERIAL_ARM_study

// EOF study_serial.c