8b5f306851
- Variable spindle speed output as a configuration option. Thanks @EliteEng! When enabled, the Z-limit (D11) and spindle enable(D12) pins switch to allow access to the hardware PWM output on pin D11. Otherwise, everything should work as it does. - Removed option for inverting the spindle and coolant enable pins. This is a safety hazard, especially for the spindle. When Grbl initializes, all pins are momentarily low until it finishes booting. If an invert is enabled, this means the spindles can be energized briefly during this time. If users need signal inversion, it’s recommended to just wire in an inversion circuit instead. - Cleared out references to spindle variable output in terms of step signal. This isn’t complete and requires more deliberation before installing. - Cleared up and cleaned up some code and config comments.
222 lines
9.2 KiB
C
222 lines
9.2 KiB
C
/*
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limits.c - code pertaining to limit-switches and performing the homing cycle
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Part of Grbl
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Copyright (c) 2012-2014 Sungeun K. Jeon
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Copyright (c) 2009-2011 Simen Svale Skogsrud
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Grbl is free software: you can redistribute it and/or modify
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it under the terms of the GNU General Public License as published by
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the Free Software Foundation, either version 3 of the License, or
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(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
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with Grbl. If not, see <http://www.gnu.org/licenses/>.
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*/
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#include <util/delay.h>
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#include <avr/io.h>
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#include <avr/interrupt.h>
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#include <avr/wdt.h>
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#include "stepper.h"
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#include "settings.h"
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#include "nuts_bolts.h"
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#include "config.h"
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#include "spindle_control.h"
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#include "motion_control.h"
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#include "planner.h"
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#include "protocol.h"
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#include "limits.h"
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#include "report.h"
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void limits_init()
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{
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LIMIT_DDR &= ~(LIMIT_MASK); // Set as input pins
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if (bit_istrue(settings.flags,BITFLAG_INVERT_LIMIT_PINS)) {
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LIMIT_PORT &= ~(LIMIT_MASK); // Normal low operation. Requires external pull-down.
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} else {
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LIMIT_PORT |= (LIMIT_MASK); // Enable internal pull-up resistors. Normal high operation.
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}
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if (bit_istrue(settings.flags,BITFLAG_HARD_LIMIT_ENABLE)) {
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LIMIT_PCMSK |= LIMIT_MASK; // Enable specific pins of the Pin Change Interrupt
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PCICR |= (1 << LIMIT_INT); // Enable Pin Change Interrupt
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} else {
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limits_disable();
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}
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#ifdef ENABLE_SOFTWARE_DEBOUNCE
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MCUSR &= ~(1<<WDRF);
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WDTCSR |= (1<<WDCE) | (1<<WDE);
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WDTCSR = (1<<WDP0); // Set time-out at ~32msec.
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#endif
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}
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void limits_disable()
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{
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LIMIT_PCMSK &= ~LIMIT_MASK; // Disable specific pins of the Pin Change Interrupt
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PCICR &= ~(1 << LIMIT_INT); // Disable Pin Change Interrupt
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}
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// This is the Limit Pin Change Interrupt, which handles the hard limit feature. A bouncing
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// limit switch can cause a lot of problems, like false readings and multiple interrupt calls.
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// If a switch is triggered at all, something bad has happened and treat it as such, regardless
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// if a limit switch is being disengaged. It's impossible to reliably tell the state of a
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// bouncing pin without a debouncing method.
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// NOTE: Do not attach an e-stop to the limit pins, because this interrupt is disabled during
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// homing cycles and will not respond correctly. Upon user request or need, there may be a
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// special pinout for an e-stop, but it is generally recommended to just directly connect
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// your e-stop switch to the Arduino reset pin, since it is the most correct way to do this.
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#ifdef ENABLE_SOFTWARE_DEBOUNCE
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ISR(LIMIT_INT_vect) { if (!(WDTCSR & (1<<WDIE))) { WDTCSR |= (1<<WDIE); } }
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ISR(WDT_vect)
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{
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WDTCSR &= ~(1<<WDIE);
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// Ignore limit switches if already in an alarm state or in-process of executing an alarm.
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// When in the alarm state, Grbl should have been reset or will force a reset, so any pending
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// moves in the planner and serial buffers are all cleared and newly sent blocks will be
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// locked out until a homing cycle or a kill lock command. Allows the user to disable the hard
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// limit setting if their limits are constantly triggering after a reset and move their axes.
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if (sys.state != STATE_ALARM) {
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if (bit_isfalse(sys.execute,EXEC_ALARM)) {
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#ifndef LIMIT_SWITCHES_ACTIVE_HIGH
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if ((LIMIT_PIN & LIMIT_MASK) ^ LIMIT_MASK) {
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#else
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if (LIMIT_PIN & LIMIT_MASK) {
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#endif
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mc_reset(); // Initiate system kill.
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sys.execute |= EXEC_CRIT_EVENT; // Indicate hard limit critical event
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}
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}
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}
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}
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#else
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ISR(LIMIT_INT_vect)
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{
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// Ignore limit switches if already in an alarm state or in-process of executing an alarm.
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// When in the alarm state, Grbl should have been reset or will force a reset, so any pending
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// moves in the planner and serial buffers are all cleared and newly sent blocks will be
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// locked out until a homing cycle or a kill lock command. Allows the user to disable the hard
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// limit setting if their limits are constantly triggering after a reset and move their axes.
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if (sys.state != STATE_ALARM) {
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if (bit_isfalse(sys.execute,EXEC_ALARM)) {
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mc_reset(); // Initiate system kill.
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sys.execute |= EXEC_CRIT_EVENT; // Indicate hard limit critical event
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}
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}
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}
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#endif
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// Moves specified cycle axes all at homing rate, either approaching or disengaging the limit
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// switches. Homing is a special motion case, where there is only an acceleration followed
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// by abrupt asynchronous stops by each axes reaching their limit switch independently. The
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// asynchronous stops are handled by a system level axis lock mask, which prevents the stepper
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// algorithm from executing step pulses.
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// NOTE: Only the abort runtime command can interrupt this process.
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void limits_go_home(uint8_t cycle_mask, bool approach, float homing_rate)
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{
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if (sys.execute & EXEC_RESET) { return; }
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uint8_t invert_pin;
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if (bit_isfalse(settings.flags,BITFLAG_INVERT_LIMIT_PINS)) { invert_pin = approach; }
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else { invert_pin = !approach; }
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// Determine travel distance to the furthest homing switch based on user max travel settings.
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// NOTE: settings.max_travel[] is stored as a negative value.
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float max_travel = settings.max_travel[X_AXIS];
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if (max_travel > settings.max_travel[Y_AXIS]) { max_travel = settings.max_travel[Y_AXIS]; }
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if (max_travel > settings.max_travel[Z_AXIS]) { max_travel = settings.max_travel[Z_AXIS]; }
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max_travel *= -1.25; // Ensure homing switches engaged by over-estimating max travel.
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if (!approach) { max_travel = -max_travel; }
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// Set target location and rate for active axes.
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float target[N_AXIS];
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uint8_t n_active_axis = 0;
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uint8_t i;
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for (i=0; i<N_AXIS; i++) {
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if (bit_istrue(cycle_mask,bit(i))) {
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n_active_axis++;
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target[i] = max_travel;
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} else {
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target[i] = 0.0;
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}
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}
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if (bit_istrue(settings.homing_dir_mask,(1<<X_LIMIT_BIT))) { target[X_AXIS] = -target[X_AXIS]; }
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if (bit_istrue(settings.homing_dir_mask,(1<<Y_LIMIT_BIT))) { target[Y_AXIS] = -target[Y_AXIS]; }
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if (bit_istrue(settings.homing_dir_mask,(1<<Z_LIMIT_BIT))) { target[Z_AXIS] = -target[Z_AXIS]; }
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homing_rate *= sqrt(n_active_axis); // [sqrt(N_AXIS)] Adjust so individual axes all move at homing rate.
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// Setup homing axis locks based on cycle mask.
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uint8_t axislock = 0;
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if (bit_istrue(cycle_mask,bit(X_AXIS))) { axislock |= (1<<X_STEP_BIT); }
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if (bit_istrue(cycle_mask,bit(Y_AXIS))) { axislock |= (1<<Y_STEP_BIT); }
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if (bit_istrue(cycle_mask,bit(Z_AXIS))) { axislock |= (1<<Z_STEP_BIT); }
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sys.homing_axis_lock = axislock;
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// Perform homing cycle. Planner buffer should be empty, as required to initiate the homing cycle.
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uint8_t limit_state;
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plan_buffer_line(target, homing_rate, false); // Bypass mc_line(). Directly plan homing motion.
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st_prep_buffer(); // Prep first segment from newly planned block.
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st_wake_up(); // Initiate motion
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do {
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// Check limit state. Lock out cycle axes when they change.
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limit_state = LIMIT_PIN;
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if (invert_pin) { limit_state ^= LIMIT_MASK; }
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// if (axislock & (1<<X_STEP_BIT)) {
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if (limit_state & (1<<X_LIMIT_BIT)) { axislock &= ~(1<<X_STEP_BIT); }
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// }
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// if (axislock & (1<<Y_STEP_BIT)) {
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if (limit_state & (1<<Y_LIMIT_BIT)) { axislock &= ~(1<<Y_STEP_BIT); }
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// }
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// if (axislock & (1<<Z_STEP_BIT)) {
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if (limit_state & (1<<Z_LIMIT_BIT)) { axislock &= ~(1<<Z_STEP_BIT); }
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// }
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sys.homing_axis_lock = axislock;
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st_prep_buffer(); // Check and prep one segment. NOTE: Should take no longer than 200us.
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if (sys.execute & EXEC_RESET) { return; }
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} while (STEP_MASK & axislock);
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st_go_idle(); // Disable steppers. Axes motion should already be locked.
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plan_reset(); // Reset planner buffer. Ensure homing motion is cleared.
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st_reset(); // Reset step segment buffer. Ensure homing motion is cleared.
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delay_ms(settings.homing_debounce_delay); // Delay to allow transient dynamics to dissipate.
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}
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// Performs a soft limit check. Called from mc_line() only. Assumes the machine has been homed,
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// and the workspace volume is in all negative space.
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void limits_soft_check(float *target)
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{
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uint8_t idx;
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for (idx=0; idx<N_AXIS; idx++) {
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if (target[idx] > 0 || target[idx] < settings.max_travel[idx]) { // NOTE: max_travel is stored as negative
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// Force feed hold if cycle is active. All buffered blocks are guaranteed to be within
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// workspace volume so just come to a controlled stop so position is not lost. When complete
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// enter alarm mode.
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if (sys.state == STATE_CYCLE) {
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st_feed_hold();
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while (sys.state == STATE_HOLD) {
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protocol_execute_runtime();
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if (sys.abort) { return; }
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}
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}
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mc_reset(); // Issue system reset and ensure spindle and coolant are shutdown.
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sys.execute |= EXEC_CRIT_EVENT; // Indicate soft limit critical event
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protocol_execute_runtime(); // Execute to enter critical event loop and system abort
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return;
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}
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}
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}
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