fixed buffering of pace changes and general cleaning
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8a0c9fd180
commit
c07a322589
18
gcode.c
18
gcode.c
@ -126,6 +126,7 @@ void select_plane(uint8_t axis_0, uint8_t axis_1)
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// characters and signed floats (no whitespace).
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uint8_t gc_execute_line(char *line) {
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int counter = 0;
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int requires_nudge = false;
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char letter;
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double value;
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double unit_converted_value;
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@ -376,17 +377,24 @@ uint8_t gc_execute_line(char *line) {
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// Find the radius
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double radius = hypot(offset[gc.plane_axis_0], offset[gc.plane_axis_1]);
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// Prepare the arc
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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));
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printByte(')');
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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));
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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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// Rounding errors means the arcing might not land us exactly where we wanted. Thats why this
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// operation must be finalized with a linear nudge to the exact target spot.
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requires_nudge = true;
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break;
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}
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}
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mc_execute();
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if (requires_nudge) {
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mc_linear_motion(target[X_AXIS], target[Y_AXIS], target[Z_AXIS], gc.feed_rate, false);
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mc_execute();
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}
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// As far as the parser is concerned, the position is now == target. In reality the
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// motion control system might still be processing the action and the real tool position
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2
main.c
2
main.c
@ -40,7 +40,7 @@ int main(void)
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sp_init(); // initialize the serial protocol
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for(;;){
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// sleep_mode();
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sleep_mode();
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sp_process(); // process the serial protocol
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}
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return 0; /* never reached */
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@ -60,7 +60,6 @@ struct ArcMotionParameters {
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int32_t error, x2, y2; // error is always == (x**2 + y**2 - radius**2),
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// x2 is always 2*x, y2 is always 2*y
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uint8_t axis_x, axis_y; // maps the arc axes to stepper axes
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int32_t target[3]; // The target position in absolute steps
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int8_t plane_steppers[3]; // A vector with the steppers of axis_x and axis_y set to 1, the remaining 0
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int incomplete; // True if the arc has not reached its target yet
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};
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@ -102,18 +101,12 @@ void mc_dwell(uint32_t milliseconds)
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// Prepare for 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 states the number of seconds for the whole movement.
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void mc_linear_motion(double x, double y, double z, float feed_rate, int invert_feed_rate)
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{
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prepare_linear_motion(trunc(x*X_STEPS_PER_MM), trunc(y*Y_STEPS_PER_MM), trunc(z*Z_STEPS_PER_MM), feed_rate, invert_feed_rate);
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}
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// Same as mc_linear_motion but accepts target in absolute step coordinates
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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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{
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memset(&mc.linear, 0, sizeof(mc.arc));
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mc.linear.target[X_AXIS] = x;
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mc.linear.target[Y_AXIS] = y;
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mc.linear.target[Z_AXIS] = z;
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mc.linear.target[X_AXIS] = x*X_STEPS_PER_MM;
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mc.linear.target[Y_AXIS] = y*Y_STEPS_PER_MM;
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mc.linear.target[Z_AXIS] = z*Z_STEPS_PER_MM;
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mc.mode = MC_MODE_LINEAR;
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uint8_t axis; // loop variable
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@ -125,9 +118,8 @@ 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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if (mc.linear.maximum_steps == 0)
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{
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mc.mode = MC_MODE_AT_REST;
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return;
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@ -306,7 +298,6 @@ void execute_arc()
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// Update the tool position to the new actual position
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mc.position[mc.arc.axis_x] += mc.arc.x-start_x;
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mc.position[mc.arc.axis_y] += mc.arc.y-start_y;
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// Todo: Because of rounding errors we might still be off by a step or two.
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mc.mode = MC_MODE_AT_REST;
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}
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@ -324,7 +315,8 @@ void execute_go_home()
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}
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void mc_execute() {
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st_set_pace(mc.pace);
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if (mc.mode != MC_MODE_AT_REST) {
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st_buffer_pace(mc.pace);
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sp_send_execution_marker();
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while(mc.mode) { // Loop because one task might start another task
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switch(mc.mode) {
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@ -335,6 +327,7 @@ void mc_execute() {
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case MC_MODE_HOME: execute_go_home(); break;
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}
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}
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}
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}
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int mc_status()
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30
stepper.c
30
stepper.c
@ -35,16 +35,25 @@
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volatile uint8_t step_buffer[STEP_BUFFER_SIZE]; // A buffer for step instructions
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volatile int step_buffer_head = 0;
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volatile int step_buffer_tail = 0;
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volatile uint32_t current_pace;
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volatile uint32_t next_pace = 0;
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uint8_t stepper_mode = STEPPER_MODE_STOPPED;
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uint8_t echo_steps = true;
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void config_pace_timer(uint32_t microseconds);
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// This timer interrupt is executed at the pace set with set_pace. It pops one instruction from
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// the step_buffer, executes it. Then it starts timer2 in order to reset the motor port after
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// five microseconds.
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SIGNAL(SIG_OUTPUT_COMPARE1A)
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{
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if (step_buffer_head != step_buffer_tail) {
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if(step_buffer[step_buffer_tail] == 0xff) {
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// If this is not a step-instruction, but a pace-marker: change pace
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config_pace_timer(next_pace);
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next_pace = 0;
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} else {
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// Set the direction pins a nanosecond or two before you step the steppers
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STEPPING_PORT = (STEPPING_PORT & ~DIRECTION_MASK) | (step_buffer[step_buffer_tail] & DIRECTION_MASK);
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// Then pulse the stepping pins
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@ -53,6 +62,7 @@ SIGNAL(SIG_OUTPUT_COMPARE1A)
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TCNT2 = 0; // reset counter
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OCR2A = 5*TICKS_PER_MICROSECOND; // set the time
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TIMSK2 |= (1<<OCIE2A); // enable interrupt
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}
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// move the step buffer tail to the next instruction
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step_buffer_tail = (step_buffer_tail + 1) % STEP_BUFFER_SIZE;
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}
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@ -92,7 +102,7 @@ void st_init()
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sei();
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// start off with a slow pace
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st_set_pace(20000);
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config_pace_timer(20000);
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st_start();
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}
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@ -148,11 +158,20 @@ inline void st_stop()
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stepper_mode = STEPPER_MODE_STOPPED;
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}
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void st_set_pace(uint32_t microseconds)
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void st_buffer_pace(uint32_t microseconds)
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{
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// Do nothing if the pace in unchanged
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if (current_pace == microseconds) { return; }
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// If the one-element pace buffer is full, flush step buffer
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if (next_pace != 0) {
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st_synchronize();
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}
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next_pace = microseconds;
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st_buffer_step(0xff);
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}
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void config_pace_timer(uint32_t microseconds)
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{
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printString("pace = ");
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printInteger(microseconds);
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printString("\n\r");
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uint32_t ticks = microseconds*TICKS_PER_MICROSECOND;
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uint16_t ceiling;
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uint16_t prescaler;
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@ -180,6 +199,7 @@ void st_set_pace(uint32_t microseconds)
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TCCR1B = (TCCR1B & ~(0x07<<CS10)) | ((prescaler+1)<<CS10);
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// Set ceiling
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OCR1A = ceiling;
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current_pace = microseconds;
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}
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int check_limit_switches()
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1
todo.txt
1
todo.txt
@ -4,7 +4,6 @@
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* Generalize feed rate code and support inverse feed rate for arcs
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* Implement homing cycle in stepper.c
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* Implement limit switch support in stepper.c (use port-triggered interrupts?)
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* How to implement st_set_pace? Consider synchronizing when pace is changed
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* How on earth am I going to deal with arcs in setups that have different steps/mm on each axis? Must
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support elipses?! Oh no.
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* Support helical interpolation
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