89a3b37e02
- Grbl now tracks both home and work (G92) coordinate systems and does live updates when G92 is called. - Rudimentary home and work position status reporting. Works but still under major construction. - Updated the main streaming script. Has a disabled periodic timer for querying status reports, disabled only because the Python timer doesn't consistently restart after the script exits. Add here only for user testing. - Fixed a bug to prevent an endless serial_write loop during status reports. - Refactored the planner variables to make it more clear what they are and make it easier for clear them.
202 lines
9.7 KiB
C
202 lines
9.7 KiB
C
/*
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motion_control.c - high level interface for issuing motion commands
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Part of Grbl
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Copyright (c) 2009-2011 Simen Svale Skogsrud
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Copyright (c) 2011 Sungeun K. Jeon
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Copyright (c) 2011 Jens Geisler
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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 <avr/io.h>
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#include "settings.h"
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#include "config.h"
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#include "motion_control.h"
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#include <util/delay.h>
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#include <math.h>
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#include <stdlib.h>
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#include "nuts_bolts.h"
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#include "stepper.h"
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#include "planner.h"
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#include "limits.h"
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#include "protocol.h"
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// Execute linear motion in absolute millimeter coordinates. Feed rate given in millimeters/second
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// unless invert_feed_rate is true. Then the feed_rate means that the motion should be completed in
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// (1 minute)/feed_rate time.
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// NOTE: This is the primary gateway to the grbl planner. All line motions, including arc line
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// segments, must pass through this routine before being passed to the planner. The seperation of
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// mc_line and plan_buffer_line is done primarily to make backlash compensation integration simple
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// and direct.
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// TODO: Check for a better way to avoid having to push the arguments twice for non-backlash cases.
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// However, this keeps the memory requirements lower since it doesn't have to call and hold two
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// plan_buffer_lines in memory. Grbl only has to retain the original line input variables during a
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// backlash segment(s).
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void mc_line(double x, double y, double z, double feed_rate, uint8_t invert_feed_rate)
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{
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// TODO: Backlash compensation may be installed here. Only need direction info to track when
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// to insert a backlash line motion(s) before the intended line motion. Requires its own
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// plan_check_full_buffer() and check for system abort loop. Also for position reporting
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// backlash steps will need to be also tracked. Not sure what the best strategy is for this,
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// i.e. keep the planner independent and do the computations in the status reporting, or let
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// the planner handle the position corrections. The latter may get complicated.
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// If the buffer is full: good! That means we are well ahead of the robot.
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// Remain in this loop until there is room in the buffer.
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do {
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protocol_execute_runtime(); // Check for any run-time commands
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if (sys.abort) { return; } // Bail, if system abort.
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} while ( plan_check_full_buffer() );
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plan_buffer_line(x, y, z, feed_rate, invert_feed_rate);
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// Auto-cycle start immediately after planner finishes. Enabled/disabled by grbl settings. During
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// a feed hold, auto-start is disabled momentarily until the cycle is resumed by the cycle-start
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// runtime command.
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// NOTE: This is allows the user to decide to exclusively use the cycle start runtime command to
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// begin motion or let grbl auto-start it for them. This is useful when: manually cycle-starting
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// when the buffer is completely full and primed; auto-starting, if there was only one g-code
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// command sent during manual operation; or if a system is prone to buffer starvation, auto-start
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// helps make sure it minimizes any dwelling/motion hiccups and keeps the cycle going.
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if (sys.auto_start) { st_cycle_start(); }
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}
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// Execute an arc in offset mode format. position == current xyz, target == target xyz,
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// offset == offset from current xyz, axis_XXX defines circle plane in tool space, axis_linear is
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// the direction of helical travel, radius == circle radius, isclockwise boolean. Used
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// for vector transformation direction.
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// The arc is approximated by generating a huge number of tiny, linear segments. The length of each
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// segment is configured in settings.mm_per_arc_segment.
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void mc_arc(double *position, double *target, double *offset, uint8_t axis_0, uint8_t axis_1,
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uint8_t axis_linear, double feed_rate, uint8_t invert_feed_rate, double radius, uint8_t isclockwise)
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{
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double center_axis0 = position[axis_0] + offset[axis_0];
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double center_axis1 = position[axis_1] + offset[axis_1];
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double linear_travel = target[axis_linear] - position[axis_linear];
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double r_axis0 = -offset[axis_0]; // Radius vector from center to current location
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double r_axis1 = -offset[axis_1];
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double rt_axis0 = target[axis_0] - center_axis0;
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double rt_axis1 = target[axis_1] - center_axis1;
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// CCW angle between position and target from circle center. Only one atan2() trig computation required.
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double angular_travel = atan2(r_axis0*rt_axis1-r_axis1*rt_axis0, r_axis0*rt_axis0+r_axis1*rt_axis1);
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if (angular_travel < 0) { angular_travel += 2*M_PI; }
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if (isclockwise) { angular_travel -= 2*M_PI; }
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double millimeters_of_travel = hypot(angular_travel*radius, fabs(linear_travel));
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if (millimeters_of_travel == 0.0) { return; }
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uint16_t segments = floor(millimeters_of_travel/settings.mm_per_arc_segment);
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// Multiply inverse feed_rate to compensate for the fact that this movement is approximated
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// by a number of discrete segments. The inverse feed_rate should be correct for the sum of
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// all segments.
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if (invert_feed_rate) { feed_rate *= segments; }
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double theta_per_segment = angular_travel/segments;
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double linear_per_segment = linear_travel/segments;
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/* Vector rotation by transformation matrix: r is the original vector, r_T is the rotated vector,
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and phi is the angle of rotation. Based on the solution approach by Jens Geisler.
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r_T = [cos(phi) -sin(phi);
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sin(phi) cos(phi] * r ;
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For arc generation, the center of the circle is the axis of rotation and the radius vector is
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defined from the circle center to the initial position. Each line segment is formed by successive
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vector rotations. This requires only two cos() and sin() computations to form the rotation
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matrix for the duration of the entire arc. Error may accumulate from numerical round-off, since
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all double numbers are single precision on the Arduino. (True double precision will not have
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round off issues for CNC applications.) Single precision error can accumulate to be greater than
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tool precision in some cases. Therefore, arc path correction is implemented.
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Small angle approximation may be used to reduce computation overhead further. This approximation
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holds for everything, but very small circles and large mm_per_arc_segment values. In other words,
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theta_per_segment would need to be greater than 0.1 rad and N_ARC_CORRECTION would need to be large
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to cause an appreciable drift error. N_ARC_CORRECTION~=25 is more than small enough to correct for
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numerical drift error. N_ARC_CORRECTION may be on the order a hundred(s) before error becomes an
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issue for CNC machines with the single precision Arduino calculations.
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This approximation also allows mc_arc to immediately insert a line segment into the planner
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without the initial overhead of computing cos() or sin(). By the time the arc needs to be applied
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a correction, the planner should have caught up to the lag caused by the initial mc_arc overhead.
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This is important when there are successive arc motions.
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*/
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// Vector rotation matrix values
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double cos_T = 1-0.5*theta_per_segment*theta_per_segment; // Small angle approximation
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double sin_T = theta_per_segment;
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double arc_target[3];
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double sin_Ti;
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double cos_Ti;
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double r_axisi;
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uint16_t i;
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int8_t count = 0;
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// Initialize the linear axis
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arc_target[axis_linear] = position[axis_linear];
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for (i = 1; i<segments; i++) { // Increment (segments-1)
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if (count < N_ARC_CORRECTION) {
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// Apply vector rotation matrix
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r_axisi = r_axis0*sin_T + r_axis1*cos_T;
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r_axis0 = r_axis0*cos_T - r_axis1*sin_T;
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r_axis1 = r_axisi;
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count++;
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} else {
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// Arc correction to radius vector. Computed only every N_ARC_CORRECTION increments.
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// Compute exact location by applying transformation matrix from initial radius vector(=-offset).
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cos_Ti = cos(i*theta_per_segment);
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sin_Ti = sin(i*theta_per_segment);
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r_axis0 = -offset[axis_0]*cos_Ti + offset[axis_1]*sin_Ti;
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r_axis1 = -offset[axis_0]*sin_Ti - offset[axis_1]*cos_Ti;
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count = 0;
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}
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// Update arc_target location
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arc_target[axis_0] = center_axis0 + r_axis0;
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arc_target[axis_1] = center_axis1 + r_axis1;
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arc_target[axis_linear] += linear_per_segment;
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mc_line(arc_target[X_AXIS], arc_target[Y_AXIS], arc_target[Z_AXIS], feed_rate, invert_feed_rate);
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// Bail mid-circle on system abort. Runtime command check already performed by mc_line.
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if (sys.abort) { return; }
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}
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// Ensure last segment arrives at target location.
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mc_line(target[X_AXIS], target[Y_AXIS], target[Z_AXIS], feed_rate, invert_feed_rate);
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}
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// Execute dwell in seconds.
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void mc_dwell(double seconds)
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{
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uint16_t i = floor(1000/DWELL_TIME_STEP*seconds);
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plan_synchronize();
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_delay_ms(floor(1000*seconds-i*DWELL_TIME_STEP)); // Delay millisecond remainder
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while (i > 0) {
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// NOTE: Check and execute runtime commands during dwell every <= DWELL_TIME_STEP milliseconds.
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protocol_execute_runtime();
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if (sys.abort) { return; }
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_delay_ms(DWELL_TIME_STEP); // Delay DWELL_TIME_STEP increment
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i--;
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}
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}
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// TODO: Update limits and homing cycle subprograms for better integration with new features.
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void mc_go_home()
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{
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limits_go_home();
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plan_set_current_position(0,0,0);
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}
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