grbl-LPC-CoreXY/grbl/serial.c

/*
  serial.c - Low level functions for sending and recieving bytes via the serial port
  Part of Grbl

  Copyright (c) 2011-2016 Sungeun K. Jeon for Gnea Research LLC
  Copyright (c) 2009-2011 Simen Svale Skogsrud

  Grbl is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
  the Free Software Foundation, either version 3 of the License, or
  (at your option) any later version.

  Grbl is distributed in the hope that it will be useful,
  but WITHOUT ANY WARRANTY; without even the implied warranty of
  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
  GNU General Public License for more details.

  You should have received a copy of the GNU General Public License
  along with Grbl.  If not, see <http://www.gnu.org/licenses/>.
*/

#include "grbl.h"

#define USE_USB

#ifdef USE_USB
#include "usbSerial.h"
#else
#include "Driver_USART.h"
#endif

#define RX_RING_BUFFER (RX_BUFFER_SIZE+1)
#define TX_RING_BUFFER (TX_BUFFER_SIZE+1)

uint8_t serial_rx_buffer[RX_RING_BUFFER];
uint16_t serial_rx_buffer_head = 0;
volatile uint16_t serial_rx_buffer_tail = 0;

uint8_t serial_tx_buffer[TX_RING_BUFFER];
uint8_t serial_tx_buffer_head = 0;
volatile uint8_t serial_tx_buffer_tail = 0;

#ifndef USE_USB
extern ARM_DRIVER_USART Driver_USART0;
#define serialDriver Driver_USART0
#endif

void serialInterrupt(uint32_t event);
void legacy_ISR(uint8_t data);
uint8_t arm_rx_buf[1];

bool lastDtr = false;

// Returns the number of bytes available in the RX serial buffer.
uint16_t serial_get_rx_buffer_available()
{
  uint16_t rtail = serial_rx_buffer_tail; // Copy to limit multiple calls to volatile
  if (serial_rx_buffer_head >= rtail) { return(RX_BUFFER_SIZE - (serial_rx_buffer_head-rtail)); }
  return((rtail-serial_rx_buffer_head-1));
}


// Returns the number of bytes used in the RX serial buffer.
// NOTE: Deprecated. Not used unless classic status reports are enabled in config.h.
uint16_t serial_get_rx_buffer_count()
{
  uint16_t rtail = serial_rx_buffer_tail; // Copy to limit multiple calls to volatile
  if (serial_rx_buffer_head >= rtail) { return(serial_rx_buffer_head-rtail); }
  return (RX_BUFFER_SIZE - (rtail-serial_rx_buffer_head));
}


// Returns the number of bytes used in the TX serial buffer.
// NOTE: Not used except for debugging and ensuring no TX bottlenecks.
uint8_t serial_get_tx_buffer_count()
{
  uint8_t ttail = serial_tx_buffer_tail; // Copy to limit multiple calls to volatile
  if (serial_tx_buffer_head >= ttail) { return(serial_tx_buffer_head-ttail); }
  return (TX_RING_BUFFER - (ttail-serial_tx_buffer_head));
}

void serial_init()
{
#ifdef USE_USB
  usbSerialInit(
    [](bool dtr, bool rts) {
      if (dtr != lastDtr)
      {
        lastDtr = dtr;
        mc_reset();
      }
    },
    [](const U8* data, unsigned len) {
      while (len--)
        legacy_ISR(*data++);
    });
#else
  int32_t uartFlags = ARM_USART_MODE_ASYNCHRONOUS |
                      ARM_USART_DATA_BITS_8 |
                      ARM_USART_PARITY_NONE |
                      ARM_USART_STOP_BITS_1 |
                      ARM_USART_FLOW_CONTROL_NONE;

  serialDriver.Initialize(serialInterrupt);
  serialDriver.PowerControl(ARM_POWER_FULL);
  serialDriver.Control(uartFlags, 115200);
  serialDriver.Control(ARM_USART_CONTROL_TX, 1);
  serialDriver.Control(ARM_USART_CONTROL_RX, 1);

  //Issue first read
  serialDriver.Receive(arm_rx_buf, 1);
#endif
}

void legacy_serial_init()
{
  // Set baud rate
  #if BAUD_RATE < 57600
    uint16_t UBRR0_value = ((F_CPU / (8L * BAUD_RATE)) - 1)/2 ;
    UCSR0A &= ~(1 << U2X0); // baud doubler off  - Only needed on Uno XXX
  #else
    uint16_t UBRR0_value = ((F_CPU / (4L * BAUD_RATE)) - 1)/2;
    UCSR0A |= (1 << U2X0);  // baud doubler on for high baud rates, i.e. 115200
  #endif
  UBRR0H = UBRR0_value >> 8;
  UBRR0L = UBRR0_value;

  // enable rx, tx, and interrupt on complete reception of a byte
  UCSR0B |= (1<<RXEN0 | 1<<TXEN0 | 1<<RXCIE0);

  // defaults to 8-bit, no parity, 1 stop bit
}

// Writes one byte to the TX serial buffer. Called by main program.
void serial_write(uint8_t data) {
#ifdef USE_USB
  while(VCOM_putchar(data) == EOF) {
    // TODO: Restructure st_prep_buffer() calls to be executed here during a long print.
    if (sys_rt_exec_state & EXEC_RESET) { return; } // Only check for abort to avoid an endless loop.
  }
#else
  //We're just really cheating here. We dont need the grbl fifo because the driver already
  //provides one. But we have to have a place to keep the data safe until the driver has completed
  //the transmit and is ready for more bytes.

  while (serialDriver.GetStatus().tx_busy) {
    // TODO: Restructure st_prep_buffer() calls to be executed here during a long print.
    if (sys_rt_exec_state & EXEC_RESET) { return; } // Only check for abort to avoid an endless loop.
  }

  //Issue the write to the driver, bypassing our tx fifo (driver has one already), and bypassing
  // the original GRBL TX Interrupt.
  serial_tx_buffer[0] = data;
  serialDriver.Send(serial_tx_buffer, 1);
#endif
}

// Writes one byte to the TX serial buffer. Called by main program.
void legacy_serial_write(uint8_t data) {
  // Calculate next head
  uint8_t next_head = serial_tx_buffer_head + 1;
  if (next_head == TX_RING_BUFFER) { next_head = 0; }

  // Wait until there is space in the buffer
  while (next_head == serial_tx_buffer_tail) {
    // TODO: Restructure st_prep_buffer() calls to be executed here during a long print.
    if (sys_rt_exec_state & EXEC_RESET) { return; } // Only check for abort to avoid an endless loop.
  }

  // Store data and advance head
  serial_tx_buffer[serial_tx_buffer_head] = data;
  serial_tx_buffer_head = next_head;

  // Enable Data Register Empty Interrupt to make sure tx-streaming is running
  UCSR0B |=  (1 << UDRIE0);
}

//Device driver interrupt
// The CMSIS Driver doesn't have seperate interrupts/callbacks available for TX and RX but instead
// is a single composite interrupt.
#ifndef USE_USB
void serialInterrupt(uint32_t event) {
  if (event & ARM_USART_EVENT_RECEIVE_COMPLETE) {
    //We got our single byte read, so put the data into our fifo and issue another read
    legacy_ISR(arm_rx_buf[0]);
    serialDriver.Receive(arm_rx_buf, 1);
  }
}
#endif

//We don't use TX interrupts directly with the ARM Driver.
// Data Register Empty Interrupt handler
void legacy_TX_ISR(void* SERIAL_UDRE)
{
  uint8_t tail = serial_tx_buffer_tail; // Temporary serial_tx_buffer_tail (to optimize for volatile)

  // Send a byte from the buffer
  UDR0 = serial_tx_buffer[tail];

  // Update tail position
  tail++;
  if (tail == TX_RING_BUFFER) { tail = 0; }

  serial_tx_buffer_tail = tail;

  // Turn off Data Register Empty Interrupt to stop tx-streaming if this concludes the transfer
  if (tail == serial_tx_buffer_head) { UCSR0B &= ~(1 << UDRIE0); }
}


// Fetches the first byte in the serial read buffer. Called by main program.
uint8_t serial_read()
{
  uint16_t tail = serial_rx_buffer_tail; // Temporary serial_rx_buffer_tail (to optimize for volatile)
  if (serial_rx_buffer_head == tail) {
    return SERIAL_NO_DATA;
  } else {
    uint8_t data = serial_rx_buffer[tail];

    tail++;
    if (tail == RX_RING_BUFFER) { tail = 0; }
    serial_rx_buffer_tail = tail;

    return data;
  }
}

//Legacy ISR, slightly modified to receive data from ARM callback (serialInterrupt) above.
void legacy_ISR(uint8_t data)
{
  uint16_t next_head;

  // Pick off realtime command characters directly from the serial stream. These characters are
  // not passed into the main buffer, but these set system state flag bits for realtime execution.
  switch (data) {
    case CMD_RESET:         mc_reset(); break; // Call motion control reset routine.
    case CMD_STATUS_REPORT: system_set_exec_state_flag(EXEC_STATUS_REPORT); break; // Set as true
    case CMD_CYCLE_START:   system_set_exec_state_flag(EXEC_CYCLE_START); break; // Set as true
    case CMD_FEED_HOLD:     system_set_exec_state_flag(EXEC_FEED_HOLD); break; // Set as true
    default :
      if (data > 0x7F) { // Real-time control characters are extended ACSII only.
        switch(data) {
          case CMD_SAFETY_DOOR:   system_set_exec_state_flag(EXEC_SAFETY_DOOR); break; // Set as true
          case CMD_JOG_CANCEL:   
            if (sys.state & STATE_JOG) { // Block all other states from invoking motion cancel.
              system_set_exec_state_flag(EXEC_MOTION_CANCEL); 
            }
            break; 
          #ifdef DEBUG
            case CMD_DEBUG_REPORT: {uint8_t sreg = SREG; cli(); bit_true(sys_rt_exec_debug,EXEC_DEBUG_REPORT); SREG = sreg;} break;
          #endif
          case CMD_FEED_OVR_RESET: system_set_exec_motion_override_flag(EXEC_FEED_OVR_RESET); break;
          case CMD_FEED_OVR_COARSE_PLUS: system_set_exec_motion_override_flag(EXEC_FEED_OVR_COARSE_PLUS); break;
          case CMD_FEED_OVR_COARSE_MINUS: system_set_exec_motion_override_flag(EXEC_FEED_OVR_COARSE_MINUS); break;
          case CMD_FEED_OVR_FINE_PLUS: system_set_exec_motion_override_flag(EXEC_FEED_OVR_FINE_PLUS); break;
          case CMD_FEED_OVR_FINE_MINUS: system_set_exec_motion_override_flag(EXEC_FEED_OVR_FINE_MINUS); break;
          case CMD_RAPID_OVR_RESET: system_set_exec_motion_override_flag(EXEC_RAPID_OVR_RESET); break;
          case CMD_RAPID_OVR_MEDIUM: system_set_exec_motion_override_flag(EXEC_RAPID_OVR_MEDIUM); break;
          case CMD_RAPID_OVR_LOW: system_set_exec_motion_override_flag(EXEC_RAPID_OVR_LOW); break;
          case CMD_SPINDLE_OVR_RESET: system_set_exec_accessory_override_flag(EXEC_SPINDLE_OVR_RESET); break;
          case CMD_SPINDLE_OVR_COARSE_PLUS: system_set_exec_accessory_override_flag(EXEC_SPINDLE_OVR_COARSE_PLUS); break;
          case CMD_SPINDLE_OVR_COARSE_MINUS: system_set_exec_accessory_override_flag(EXEC_SPINDLE_OVR_COARSE_MINUS); break;
          case CMD_SPINDLE_OVR_FINE_PLUS: system_set_exec_accessory_override_flag(EXEC_SPINDLE_OVR_FINE_PLUS); break;
          case CMD_SPINDLE_OVR_FINE_MINUS: system_set_exec_accessory_override_flag(EXEC_SPINDLE_OVR_FINE_MINUS); break;
          case CMD_SPINDLE_OVR_STOP: system_set_exec_accessory_override_flag(EXEC_SPINDLE_OVR_STOP); break;
          case CMD_COOLANT_FLOOD_OVR_TOGGLE: system_set_exec_accessory_override_flag(EXEC_COOLANT_FLOOD_OVR_TOGGLE); break;
          #ifdef ENABLE_M7
            case CMD_COOLANT_MIST_OVR_TOGGLE: system_set_exec_accessory_override_flag(EXEC_COOLANT_MIST_OVR_TOGGLE); break;
          #endif
        }
        // Throw away any unfound extended-ASCII character by not passing it to the serial buffer.
      } else { // Write character to buffer
        next_head = serial_rx_buffer_head + 1;
        if (next_head == RX_RING_BUFFER) { next_head = 0; }

        // Write data to buffer unless it is full.
        if (next_head != serial_rx_buffer_tail) {
          serial_rx_buffer[serial_rx_buffer_head] = data;
          serial_rx_buffer_head = next_head;
        }
      }
  }
}


void serial_reset_read_buffer()
{
  serial_rx_buffer_tail = serial_rx_buffer_head;
}