presumably fixed the feed rate computation
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d012440518
5
config.h
5
config.h
@ -21,7 +21,7 @@
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#ifndef config_h
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#define config_h
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#define VERSION "0.1"
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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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@ -64,9 +64,6 @@
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#define BAUD_RATE 19200
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// Unrolling the arc code is faster, but consumes about 830 extra bytes of code space.
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// #define UNROLLED_ARC_LOOP
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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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#define STEPPING_MASK STEP_MASK | DIRECTION_MASK
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@ -34,6 +34,7 @@
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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 "serial_protocol.h"
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#include "wiring_serial.h"
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@ -50,6 +51,7 @@ struct LinearMotionParameters {
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};
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struct ArcMotionParameters {
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int8_t direction[3]; // The direction of travel along each axis (-1, 0 or 1)
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int8_t angular_direction; // 1 = clockwise, -1 = anticlockwise
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int32_t x, y, target_x, target_y; // current position and target position in the
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// local coordinate system of the arc-generator where [0,0] is the
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@ -80,7 +82,6 @@ struct MotionControlState {
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};
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struct MotionControlState mc;
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void set_stepper_directions(int8_t *direction);
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inline void step_steppers(uint8_t *enabled);
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inline void step_axis(uint8_t axis);
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@ -118,6 +119,8 @@ void mc_linear_motion(double x, double y, double z, float feed_rate, int invert_
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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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@ -149,13 +152,15 @@ void prepare_linear_motion(uint32_t x, uint32_t y, uint32_t z, float feed_rate,
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mc.pace =
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(feed_rate*1000000)/mc.linear.maximum_steps;
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} else {
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// Ask old Phytagoras to estimate how many steps our next move is going to take us:
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uint32_t steps_to_travel =
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ceil(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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// 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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// 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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((steps_to_travel * ONE_MINUTE_OF_MICROSECONDS) / feed_rate) / mc.linear.maximum_steps;
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round(((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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@ -194,6 +199,7 @@ void execute_linear_motion()
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// ISSUE: The arc interpolator assumes all axes have the same steps/mm as the X axis.
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void mc_arc(double theta, double angular_travel, double radius, int axis_1, int axis_2, double feed_rate)
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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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mc.mode = MC_MODE_ARC;
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// Determine angular direction (+1 = clockwise, -1 = counterclockwise)
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@ -216,15 +222,20 @@ void mc_arc(double theta, double angular_travel, double radius, int axis_1, int
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mc.arc.y2 = 2*mc.arc.y;
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// Set up a vector with the steppers we are going to use tracing the plane of this arc
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clear_vector(mc.arc.plane_steppers);
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mc.arc.plane_steppers[axis_1] = 1;
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mc.arc.plane_steppers[axis_2] = 1;
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// And map the local coordinate system of the arc onto the tool axes of the selected plane
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mc.arc.axis_x = axis_1;
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mc.arc.axis_y = axis_2;
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// mm/second -> microseconds/step. Assumes all axes have the same steps/mm as the x axis
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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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// 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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// 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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ONE_MINUTE_OF_MICROSECONDS / (feed_rate * X_STEPS_PER_MM);
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round(((millimeters_circumference * ONE_MINUTE_OF_MICROSECONDS) / feed_rate) / steps_in_full_circle);
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mc.arc.incomplete = true;
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}
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@ -279,7 +290,6 @@ void execute_arc()
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uint32_t start_x = mc.arc.x;
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uint32_t start_y = mc.arc.y;
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int dx, dy; // Trace directions
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int8_t direction[3];
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// mc.mode is set to 0 (MC_MODE_AT_REST) when target is reached
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while(mc.arc.incomplete)
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@ -289,9 +299,9 @@ void execute_arc()
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// Take dx and dy which are local to the arc being generated and map them on to the
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// selected tool-space-axes for the current arc.
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direction[mc.arc.axis_x] = dx;
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direction[mc.arc.axis_y] = dy;
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set_stepper_directions(direction);
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mc.arc.direction[mc.arc.axis_x] = dx;
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mc.arc.direction[mc.arc.axis_y] = dy;
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set_stepper_directions(mc.arc.direction);
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if (abs(mc.arc.x)<abs(mc.arc.y)) {
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step_arc_along_x(dx,dy);
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@ -303,9 +313,7 @@ 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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// Because of rounding errors we might be off by a step or two. Adjust for this
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// To be implemented
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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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// 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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@ -323,8 +331,8 @@ 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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printByte('~');
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st_set_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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case MC_MODE_AT_REST: break;
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@ -36,6 +36,12 @@ void prompt() {
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line_counter = 0;
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}
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void sp_send_execution_marker()
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{
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printByte(EXECUTION_MARKER);
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}
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void print_result() {
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double position[3];
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int inches_mode;
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@ -77,20 +83,18 @@ 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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//printByte(c); // Echo
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if(c == '\r') {
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if(c == '\r') { // Line is complete. Then execute!
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line[line_counter] = 0;
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//printByte(EXECUTION_MARKER);
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gc_execute_line(line);
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line_counter = 0;
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print_result();
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prompt();
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} else if (c == ' ' || c == '\t') {
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// Throw away whitepace
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} else if (c >= 'a' && c <= 'z') {
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} else if (c == ' ' || c == '\t') { // Throw away whitepace
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} else if (c >= 'a' && c <= 'z') { // Upcase lowercase
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line[line_counter++] = c-'a'+'A';
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} else {
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line[line_counter++] = c;
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}
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}
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}
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@ -25,7 +25,12 @@
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// A character to acknowledge that the execution has started
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#define EXECUTION_MARKER '~'
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// Initialize the serial protocol
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void sp_init();
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// Called by motion control just before the motion starts
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void sp_send_execution_marker();
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// Read command lines from the serial port and execute them as they
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// come in. Blocks until the serial buffer is emptied.
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void sp_process();
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#endif
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@ -100,7 +100,6 @@ void st_buffer_step(uint8_t motor_port_bits)
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{
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if (echo_steps) {
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printByte('!'+motor_port_bits);
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// printIntegerInBase(motor_port_bits,2);printByte('\r');printByte('\n');
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}
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int i = (step_buffer_head + 1) % STEP_BUFFER_SIZE;
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2
todo.txt
2
todo.txt
@ -1,3 +1,5 @@
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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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* 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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