grbl-LPC-CoreXY/serial.c

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/*
serial.c - Low level functions for sending and recieving bytes via the serial port
Part of Grbl
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Copyright (c) 2009-2011 Simen Svale Skogsrud
Copyright (c) 2011-2012 Sungeun K. Jeon
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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.
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Grbl is distributed in the hope that it will be useful,
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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.
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You should have received a copy of the GNU General Public License
along with Grbl. If not, see <http://www.gnu.org/licenses/>.
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*/
/* This code was initially inspired by the wiring_serial module by David A. Mellis which
used to be a part of the Arduino project. */
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#include <avr/interrupt.h>
#include "serial.h"
#include "config.h"
#include "motion_control.h"
#include "protocol.h"
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uint8_t rx_buffer[RX_BUFFER_SIZE];
uint8_t rx_buffer_head = 0;
uint8_t rx_buffer_tail = 0;
uint8_t tx_buffer[TX_BUFFER_SIZE];
uint8_t tx_buffer_head = 0;
volatile uint8_t tx_buffer_tail = 0;
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#ifdef ENABLE_XONXOFF
volatile uint8_t flow_ctrl = XON_SENT; // Flow control state variable
// Returns the number of bytes in the RX buffer. This replaces a typical byte counter to prevent
// the interrupt and main programs from writing to the counter at the same time.
static uint8_t get_rx_buffer_count()
{
if (rx_buffer_head == rx_buffer_tail) { return(0); }
if (rx_buffer_head < rx_buffer_tail) { return(rx_buffer_tail-rx_buffer_head); }
return (RX_BUFFER_SIZE - (rx_buffer_head-rx_buffer_tail));
}
#endif
Re-factored system states and alarm management. Serial baud support greater than 57600. - Refactored system states to be more clear and concise. Alarm locks processes when position is unknown to indicate to user something has gone wrong. - Changed mc_alarm to mc_reset, which now manages the system reset function. Centralizes it. - Renamed '$X' kill homing lock to kill alarm lock. - Created an alarm error reporting method to clear up what is an alarm: message vs a status error: message. For GUIs mainly. Alarm codes are negative. Status codes are positive. - Serial baud support upto 115200. Previous baudrate calc was unstable for 57600 and above. - Alarm state locks out all g-code blocks, including startup scripts, but allows user to access settings and internal commands. For example, to disable hard limits, if they are problematic. - Hard limits do not respond in an alarm state. - Fixed a problem with the hard limit interrupt during the homing cycle. The interrupt register is still active during the homing cycle and still signal the interrupt to trigger when re-enabled. Instead, just disabled the register. - Homing rate adjusted. All axes move at homing seek rate, regardless of how many axes move at the same time. This is unlike how the stepper module does it as a point to point rate. - New config.h settings to disable the homing rate adjustment and the force homing upon powerup. - Reduced the number of startup lines back down to 2 from 3. This discourages users from placing motion block in there, which can be very dangerous. - Startup blocks now run only after an alarm-free reset or after a homing cycle. Does not run when $X kill is called. For satefy reasons
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void serial_init()
{
// Set baud rate
#if BAUD_RATE < 57600
uint16_t UBRR0_value = ((F_CPU / (8L * BAUD_RATE)) - 1)/2 ;
UCSR0A &= ~(1 << U2X0); // baud doubler off - Only needed on Uno XXX
#else
uint16_t UBRR0_value = ((F_CPU / (4L * BAUD_RATE)) - 1)/2;
UCSR0A |= (1 << U2X0); // baud doubler on for high baud rates, i.e. 115200
#endif
UBRR0H = UBRR0_value >> 8;
UBRR0L = UBRR0_value;
Re-factored system states and alarm management. Serial baud support greater than 57600. - Refactored system states to be more clear and concise. Alarm locks processes when position is unknown to indicate to user something has gone wrong. - Changed mc_alarm to mc_reset, which now manages the system reset function. Centralizes it. - Renamed '$X' kill homing lock to kill alarm lock. - Created an alarm error reporting method to clear up what is an alarm: message vs a status error: message. For GUIs mainly. Alarm codes are negative. Status codes are positive. - Serial baud support upto 115200. Previous baudrate calc was unstable for 57600 and above. - Alarm state locks out all g-code blocks, including startup scripts, but allows user to access settings and internal commands. For example, to disable hard limits, if they are problematic. - Hard limits do not respond in an alarm state. - Fixed a problem with the hard limit interrupt during the homing cycle. The interrupt register is still active during the homing cycle and still signal the interrupt to trigger when re-enabled. Instead, just disabled the register. - Homing rate adjusted. All axes move at homing seek rate, regardless of how many axes move at the same time. This is unlike how the stepper module does it as a point to point rate. - New config.h settings to disable the homing rate adjustment and the force homing upon powerup. - Reduced the number of startup lines back down to 2 from 3. This discourages users from placing motion block in there, which can be very dangerous. - Startup blocks now run only after an alarm-free reset or after a homing cycle. Does not run when $X kill is called. For satefy reasons
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// enable rx and tx
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UCSR0B |= 1<<RXEN0;
UCSR0B |= 1<<TXEN0;
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// enable interrupt on complete reception of a byte
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UCSR0B |= 1<<RXCIE0;
// defaults to 8-bit, no parity, 1 stop bit
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}
void serial_write(uint8_t data) {
// Calculate next head
uint8_t next_head = tx_buffer_head + 1;
if (next_head == TX_BUFFER_SIZE) { next_head = 0; }
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// Wait until there is space in the buffer
while (next_head == tx_buffer_tail) {
if (sys.execute & EXEC_RESET) { return; } // Only check for abort to avoid an endless loop.
}
// Store data and advance head
tx_buffer[tx_buffer_head] = data;
tx_buffer_head = next_head;
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// Enable Data Register Empty Interrupt to make sure tx-streaming is running
UCSR0B |= (1 << UDRIE0);
}
// Data Register Empty Interrupt handler
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ISR(SERIAL_UDRE)
{
// Temporary tx_buffer_tail (to optimize for volatile)
uint8_t tail = tx_buffer_tail;
#ifdef ENABLE_XONXOFF
if (flow_ctrl == SEND_XOFF) {
UDR0 = XOFF_CHAR;
flow_ctrl = XOFF_SENT;
} else if (flow_ctrl == SEND_XON) {
UDR0 = XON_CHAR;
flow_ctrl = XON_SENT;
} else
#endif
{
// Send a byte from the buffer
UDR0 = tx_buffer[tail];
// Update tail position
tail++;
if (tail == TX_BUFFER_SIZE) { tail = 0; }
tx_buffer_tail = tail;
}
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// Turn off Data Register Empty Interrupt to stop tx-streaming if this concludes the transfer
if (tail == tx_buffer_head) { UCSR0B &= ~(1 << UDRIE0); }
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}
uint8_t serial_read()
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{
if (rx_buffer_head == rx_buffer_tail) {
return SERIAL_NO_DATA;
} else {
uint8_t data = rx_buffer[rx_buffer_tail];
rx_buffer_tail++;
if (rx_buffer_tail == RX_BUFFER_SIZE) { rx_buffer_tail = 0; }
#ifdef ENABLE_XONXOFF
if ((get_rx_buffer_count() < RX_BUFFER_LOW) && flow_ctrl == XOFF_SENT) {
flow_ctrl = SEND_XON;
UCSR0B |= (1 << UDRIE0); // Force TX
}
#endif
return data;
}
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}
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ISR(SERIAL_RX)
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{
uint8_t data = UDR0;
uint8_t next_head;
// Pick off runtime command characters directly from the serial stream. These characters are
// not passed into the buffer, but these set system state flag bits for runtime execution.
switch (data) {
case CMD_STATUS_REPORT: sys.execute |= EXEC_STATUS_REPORT; break; // Set as true
case CMD_CYCLE_START: sys.execute |= EXEC_CYCLE_START; break; // Set as true
case CMD_FEED_HOLD: sys.execute |= EXEC_FEED_HOLD; break; // Set as true
Re-factored system states and alarm management. Serial baud support greater than 57600. - Refactored system states to be more clear and concise. Alarm locks processes when position is unknown to indicate to user something has gone wrong. - Changed mc_alarm to mc_reset, which now manages the system reset function. Centralizes it. - Renamed '$X' kill homing lock to kill alarm lock. - Created an alarm error reporting method to clear up what is an alarm: message vs a status error: message. For GUIs mainly. Alarm codes are negative. Status codes are positive. - Serial baud support upto 115200. Previous baudrate calc was unstable for 57600 and above. - Alarm state locks out all g-code blocks, including startup scripts, but allows user to access settings and internal commands. For example, to disable hard limits, if they are problematic. - Hard limits do not respond in an alarm state. - Fixed a problem with the hard limit interrupt during the homing cycle. The interrupt register is still active during the homing cycle and still signal the interrupt to trigger when re-enabled. Instead, just disabled the register. - Homing rate adjusted. All axes move at homing seek rate, regardless of how many axes move at the same time. This is unlike how the stepper module does it as a point to point rate. - New config.h settings to disable the homing rate adjustment and the force homing upon powerup. - Reduced the number of startup lines back down to 2 from 3. This discourages users from placing motion block in there, which can be very dangerous. - Startup blocks now run only after an alarm-free reset or after a homing cycle. Does not run when $X kill is called. For satefy reasons
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case CMD_RESET: mc_reset(); break; // Call motion control reset routine.
default: // Write character to buffer
next_head = rx_buffer_head + 1;
if (next_head == RX_BUFFER_SIZE) { next_head = 0; }
// Write data to buffer unless it is full.
if (next_head != rx_buffer_tail) {
rx_buffer[rx_buffer_head] = data;
rx_buffer_head = next_head;
#ifdef ENABLE_XONXOFF
if ((get_rx_buffer_count() >= RX_BUFFER_FULL) && flow_ctrl == XON_SENT) {
flow_ctrl = SEND_XOFF;
UCSR0B |= (1 << UDRIE0); // Force TX
}
#endif
}
}
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}
void serial_reset_read_buffer()
{
rx_buffer_tail = rx_buffer_head;
#ifdef ENABLE_XONXOFF
flow_ctrl = XON_SENT;
#endif
}