pace calculation correct, arc algorithm correct, support for negative R
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d012440518
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6c3a6a25d5
12
config.h
12
config.h
@ -23,17 +23,17 @@
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#define VERSION "0.0"
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#define X_STEPS_PER_MM 5.0
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#define Y_STEPS_PER_MM 5.0
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#define Z_STEPS_PER_MM 5.0
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#define X_STEPS_PER_MM 10.0
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#define Y_STEPS_PER_MM 10.0
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#define Z_STEPS_PER_MM 10.0
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#define INCHES_PER_MM 25.4
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#define X_STEPS_PER_INCH X_STEPS_PER_MM*INCHES_PER_MM
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#define Y_STEPS_PER_INCH Y_STEPS_PER_MM*INCHES_PER_MM
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#define Z_STEPS_PER_INCH Z_STEPS_PER_MM*INCHES_PER_MM
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#define RAPID_FEEDRATE 100.0 // in millimeters per minute
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#define DEFAULT_FEEDRATE 635.0
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#define RAPID_FEEDRATE 200000.0 // in millimeters per minute
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#define DEFAULT_FEEDRATE 200000.0
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#define STEPPERS_ENABLE_DDR DDRB
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#define STEPPERS_ENABLE_PORT PORTB
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@ -62,7 +62,7 @@
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#define SPINDLE_DIRECTION_PORT PORTC
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#define SPINDLE_DIRECTION_BIT 4
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#define BAUD_RATE 19200
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#define BAUD_RATE 9600
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#define STEP_MASK (1<<X_STEP_BIT)|(1<<Y_STEP_BIT)|(1<<Z_STEP_BIT)
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#define DIRECTION_MASK (1<<X_DIRECTION_BIT)|(1<<Y_DIRECTION_BIT)|(1<<Z_DIRECTION_BIT)
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35
gcode.c
35
gcode.c
@ -244,7 +244,7 @@ uint8_t gc_execute_line(char *line) {
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switch (gc.motion_mode) {
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case MOTION_MODE_CANCEL: break;
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case MOTION_MODE_RAPID_LINEAR: case MOTION_MODE_LINEAR:
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if (inverse_feed_rate) {
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if (gc.inverse_feed_rate_mode) {
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mc_linear_motion(target[X_AXIS], target[Y_AXIS], target[Z_AXIS],
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inverse_feed_rate, true);
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} else {
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@ -309,37 +309,40 @@ uint8_t gc_execute_line(char *line) {
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double x = target[gc.plane_axis_0]-gc.position[gc.plane_axis_0];
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double y = target[gc.plane_axis_1]-gc.position[gc.plane_axis_1];
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clear_vector(&offset);
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double h_x2_div_d = sqrt(4 * r*r - x*x - y*y)/hypot(x,y); // == h * 2 / d
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double h_x2_div_d = -sqrt(4 * r*r - x*x - y*y)/hypot(x,y); // == -(h * 2 / d)
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// If r is smaller than d, the arc is now traversing the complex plane beyond the reach of any
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// earthly CNC, and thus - for practical reasons - we will terminate promptly:
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// real CNC, and thus - for practical reasons - we will terminate promptly:
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if(isnan(h_x2_div_d)) { FAIL(GCSTATUS_FLOATING_POINT_ERROR); return(gc.status_code); }
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/* The anti-clockwise circle lies to the right of the target direction. When offset is positive,
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// Invert the sign of h_x2_div_d if the circle is counter clockwise (see sketch below)
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if (gc.motion_mode == MOTION_MODE_CCW_ARC) { h_x2_div_d = -h_x2_div_d; }
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/* The counter clockwise circle lies to the left of the target direction. When offset is positive,
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the left hand circle will be generated - when it is negative the right hand circle is generated.
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T
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T <-- Target position
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^
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Clockwise circles with this center | Clockwise circles with this center will have
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will have > 180 deg of angular travel | < 180 deg of angular travel, which is a good thing!
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\ | /
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center of arc when h_x2_div_d is positive -> x <----- | -----> x <- center of arc when h_x2_div_d is negative
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C */
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C <-- Current position */
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if (gc.motion_mode == MOTION_MODE_CCW_ARC) { h_x2_div_d = -h_x2_div_d; }
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// Negative R is g-code-alese for "I want a circle with more than 180 degrees of travel" (go figure!),
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// even though it is advised against ever generating such circles in a single line of g-code. By
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// inverting the sign of h_x2_div_d the center of the circles is placed on the opposide side of the line of
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// travel and thus we get the unadvisably long circles as prescribed.
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if (r < 0) { h_x2_div_d = -h_x2_div_d; }
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// Complete the operation by calculating the actual center of the arc
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offset[gc.plane_axis_0] = (x-(y*h_x2_div_d))/2;
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offset[gc.plane_axis_1] = (y+(x*h_x2_div_d))/2;
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// printByte('(');
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// printInteger(trunc(offset[gc.plane_axis_0])); printByte(',');
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// printInteger(trunc(offset[gc.plane_axis_1]));
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// printByte(')');
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}
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/*
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@ -376,7 +379,7 @@ uint8_t gc_execute_line(char *line) {
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printString("mc_arc(");
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printInteger(trunc(theta_start/M_PI*180)); printByte(',');
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printInteger(trunc(angular_travel/M_PI*180)); printByte(',');
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printInteger(trunc(radius)); printByte('…');
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printInteger(trunc(radius));
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printByte(')');
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mc_arc(theta_start, angular_travel, radius, gc.plane_axis_0, gc.plane_axis_1, gc.feed_rate);
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break;
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@ -38,7 +38,7 @@
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#include "wiring_serial.h"
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#define ONE_MINUTE_OF_MICROSECONDS 60000000
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#define ONE_MINUTE_OF_MICROSECONDS 60000000.0
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// Parameters when mode is MC_MODE_ARC
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struct LinearMotionParameters {
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@ -87,16 +87,6 @@ inline void step_steppers(uint8_t *enabled);
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inline void step_axis(uint8_t axis);
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void prepare_linear_motion(uint32_t x, uint32_t y, uint32_t z, float feed_rate, int invert_feed_rate);
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// void printCurrentPosition() {
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// int axis;
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// printString("[ ");
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// for(axis=X_AXIS; axis<=Z_AXIS; axis++) {
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// printInteger(trunc(mc.position[axis]*100));
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// printByte(' ');
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// }
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// printString("]\n\r");
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// }
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//
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void mc_init()
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{
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// Initialize state variables
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@ -135,6 +125,7 @@ void prepare_linear_motion(uint32_t x, uint32_t y, uint32_t z, float feed_rate,
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// Find the magnitude of the axis with the longest travel
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mc.linear.maximum_steps = max(mc.linear.step_count[Z_AXIS],
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max(mc.linear.step_count[X_AXIS], mc.linear.step_count[Y_AXIS]));
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if(mc.linear.maximum_steps == 0) { return; }
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// Nothing to do?
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if ((mc.linear.maximum_steps) == 0)
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{
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@ -154,13 +145,13 @@ void prepare_linear_motion(uint32_t x, uint32_t y, uint32_t z, float feed_rate,
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} else {
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// Ask old Phytagoras to estimate how many mm our next move is going to take us:
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double millimeters_to_travel =
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ceil(sqrt(pow((mc.linear.step_count[X_AXIS]),2) +
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pow((mc.linear.step_count[Y_AXIS]),2) +
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pow((mc.linear.step_count[Z_AXIS]),2)));
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sqrt(pow(X_STEPS_PER_MM*mc.linear.step_count[X_AXIS],2) +
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pow(Y_STEPS_PER_MM*mc.linear.step_count[Y_AXIS],2) +
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pow(Z_STEPS_PER_MM*mc.linear.step_count[Z_AXIS],2));
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// Calculate the microseconds between steps that we should wait in order to travel the
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// designated amount of millimeters in the amount of steps we are going to generate
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mc.pace =
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round(((millimeters_to_travel * ONE_MINUTE_OF_MICROSECONDS) / feed_rate) / mc.linear.maximum_steps);
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((millimeters_to_travel * ONE_MINUTE_OF_MICROSECONDS) / feed_rate) / mc.linear.maximum_steps;
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}
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}
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@ -201,6 +192,7 @@ void mc_arc(double theta, double angular_travel, double radius, int axis_1, int
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{
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memset(&mc.arc, 0, sizeof(mc.arc));
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uint32_t radius_steps = round(radius*X_STEPS_PER_MM);
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if(radius_steps == 0) { return; }
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mc.mode = MC_MODE_ARC;
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// Determine angular direction (+1 = clockwise, -1 = counterclockwise)
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mc.arc.angular_direction = signof(angular_travel);
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@ -229,13 +221,13 @@ void mc_arc(double theta, double angular_travel, double radius, int axis_1, int
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mc.arc.axis_y = axis_2;
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// The amount of steppings performed while tracing a full circle is equal to the sum of sides in a
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// square inscribed in the circle. We use this to estimate the amount of steps as if this arc was a full circle:
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uint32_t steps_in_full_circle = round(radius_steps * 4 * (1/sqrt(2)));
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uint32_t steps_in_half_circle = round(radius_steps * 4 * (1/sqrt(2)));
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// We then calculate the millimeters of travel along the circumference of that same full circle
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double millimeters_circumference = 2*radius*M_PI;
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double millimeters_half_circumference = radius*M_PI;
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// Then we calculate the microseconds between each step as if we will trace the full circle.
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// It doesn't matter what fraction of the circle we are actuallyt going to trace. The pace is the same.
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mc.pace =
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round(((millimeters_circumference * ONE_MINUTE_OF_MICROSECONDS) / feed_rate) / steps_in_full_circle);
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((millimeters_half_circumference * ONE_MINUTE_OF_MICROSECONDS) / feed_rate) / steps_in_half_circle;
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mc.arc.incomplete = true;
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}
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@ -244,7 +236,8 @@ void mc_arc(double theta, double angular_travel, double radius, int axis_1, int
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mc.arc.target_x * mc.arc.target_direction_y) && \
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(mc.arc.y * mc.arc.target_direction_x <= \
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mc.arc.target_y * mc.arc.target_direction_x)) \
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{ mc.arc.incomplete = false; }
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{ if ((signof(mc.arc.x) == signof(mc.arc.target_x)) && (signof(mc.arc.y) == signof(mc.arc.target_y))) \
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{ mc.arc.incomplete = false; } }
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// Internal method used by execute_arc to trace horizontally in the general direction provided by dx and dy
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void step_arc_along_x(int8_t dx, int8_t dy)
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2
scripts/console
Executable file
2
scripts/console
Executable file
@ -0,0 +1,2 @@
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socat -d -d READLINE /dev/tty.usbserial-A4001o6L,clocal=1,nonblock=1,cread=1,cs8,ixon=1,ixoff=1
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2
scripts/proxy
Executable file
2
scripts/proxy
Executable file
@ -0,0 +1,2 @@
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socat -d -d tcp4-listen:5001,fork /dev/tty.usbserial-A4001o6L,clocal=1,nonblock=1,cread=1,cs8,ixon=1,ixoff=1
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@ -83,7 +83,7 @@ void sp_process()
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char c;
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while((c = serialRead()) != -1)
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{
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if(c == '\r') { // Line is complete. Then execute!
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if((c < 32)) { // Line is complete. Then execute!
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line[line_counter] = 0;
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gc_execute_line(line);
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line_counter = 0;
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1
todo.txt
1
todo.txt
@ -1,3 +1,4 @@
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* Optimize arc target detection code utilizing the primary axis of travel
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* Use bitmasks, not vectors to build steps in motion_control
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* Arcs might be a step or two off because of FP gotchas. Must add a little nudge in the end there
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* Generalize feed rate code and support inverse feed rate for arcs
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