#include "libs/Module.h"
#include "libs/Kernel.h"
+#include "mbed.h" // for us_ticker_read()
+
#include <math.h>
#include <string>
using std::string;
#include "StepperMotor.h"
#include "Gcode.h"
#include "PublicDataRequest.h"
-#include "RobotPublicAccess.h"
+#include "PublicData.h"
#include "arm_solutions/BaseSolution.h"
#include "arm_solutions/CartesianSolution.h"
#include "arm_solutions/RotatableCartesianSolution.h"
#include "arm_solutions/LinearDeltaSolution.h"
+#include "arm_solutions/RotatableDeltaSolution.h"
#include "arm_solutions/HBotSolution.h"
+#include "arm_solutions/CoreXZSolution.h"
#include "arm_solutions/MorganSCARASolution.h"
#include "StepTicker.h"
#include "checksumm.h"
#include "ConfigValue.h"
#include "libs/StreamOutput.h"
#include "StreamOutputPool.h"
+#include "ExtruderPublicAccess.h"
#define default_seek_rate_checksum CHECKSUM("default_seek_rate")
#define default_feed_rate_checksum CHECKSUM("default_feed_rate")
#define rotatable_cartesian_checksum CHECKSUM("rotatable_cartesian")
#define rostock_checksum CHECKSUM("rostock")
#define linear_delta_checksum CHECKSUM("linear_delta")
+#define rotatable_delta_checksum CHECKSUM("rotatable_delta")
#define delta_checksum CHECKSUM("delta")
#define hbot_checksum CHECKSUM("hbot")
#define corexy_checksum CHECKSUM("corexy")
+#define corexz_checksum CHECKSUM("corexz")
#define kossel_checksum CHECKSUM("kossel")
#define morgan_checksum CHECKSUM("morgan")
#define beta_checksum CHECKSUM("beta")
#define gamma_checksum CHECKSUM("gamma")
-
#define NEXT_ACTION_DEFAULT 0
#define NEXT_ACTION_DWELL 1
#define NEXT_ACTION_GO_HOME 2
#define SPINDLE_DIRECTION_CW 0
#define SPINDLE_DIRECTION_CCW 1
+#define ARC_ANGULAR_TRAVEL_EPSILON 5E-7 // Float (radians)
+
// The Robot converts GCodes into actual movements, and then adds them to the Planner, which passes them to the Conveyor so they can be added to the queue
// It takes care of cutting arcs into segments, same thing for line that are too long
-#define max(a,b) (((a) > (b)) ? (a) : (b))
Robot::Robot()
{
this->motion_mode = MOTION_MODE_SEEK;
this->select_plane(X_AXIS, Y_AXIS, Z_AXIS);
clear_vector(this->last_milestone);
+ clear_vector(this->transformed_last_milestone);
this->arm_solution = NULL;
seconds_per_minute = 60.0F;
this->clearToolOffset();
- this->adjustZfnc= nullptr;
+ this->compensationTransform= nullptr;
}
//Called when the module has just been loaded
void Robot::on_module_loaded()
{
this->register_for_event(ON_GCODE_RECEIVED);
- this->register_for_event(ON_GET_PUBLIC_DATA);
- this->register_for_event(ON_SET_PUBLIC_DATA);
// Configuration
this->on_config_reload(this);
if(solution_checksum == hbot_checksum || solution_checksum == corexy_checksum) {
this->arm_solution = new HBotSolution(THEKERNEL->config);
+ } else if(solution_checksum == corexz_checksum) {
+ this->arm_solution = new CoreXZSolution(THEKERNEL->config);
+
} else if(solution_checksum == rostock_checksum || solution_checksum == kossel_checksum || solution_checksum == delta_checksum || solution_checksum == linear_delta_checksum) {
this->arm_solution = new LinearDeltaSolution(THEKERNEL->config);
} else if(solution_checksum == rotatable_cartesian_checksum) {
this->arm_solution = new RotatableCartesianSolution(THEKERNEL->config);
+ } else if(solution_checksum == rotatable_delta_checksum) {
+ this->arm_solution = new RotatableDeltaSolution(THEKERNEL->config);
+
+
} else if(solution_checksum == morgan_checksum) {
this->arm_solution = new MorganSCARASolution(THEKERNEL->config);
// TODO: delete or detect old steppermotors
// Make our 3 StepperMotors
- this->alpha_stepper_motor = THEKERNEL->step_ticker->add_stepper_motor( new StepperMotor(alpha_step_pin, alpha_dir_pin, alpha_en_pin) );
- this->beta_stepper_motor = THEKERNEL->step_ticker->add_stepper_motor( new StepperMotor(beta_step_pin, beta_dir_pin, beta_en_pin ) );
- this->gamma_stepper_motor = THEKERNEL->step_ticker->add_stepper_motor( new StepperMotor(gamma_step_pin, gamma_dir_pin, gamma_en_pin) );
+ this->alpha_stepper_motor = new StepperMotor(alpha_step_pin, alpha_dir_pin, alpha_en_pin);
+ this->beta_stepper_motor = new StepperMotor(beta_step_pin, beta_dir_pin, beta_en_pin );
+ this->gamma_stepper_motor = new StepperMotor(gamma_step_pin, gamma_dir_pin, gamma_en_pin);
alpha_stepper_motor->change_steps_per_mm(steps_per_mm[0]);
beta_stepper_motor->change_steps_per_mm(steps_per_mm[1]);
gamma_stepper_motor->change_steps_per_mm(steps_per_mm[2]);
- alpha_stepper_motor->max_rate = THEKERNEL->config->value(alpha_max_rate_checksum)->by_default(30000.0F)->as_number() / 60.0F;
- beta_stepper_motor->max_rate = THEKERNEL->config->value(beta_max_rate_checksum )->by_default(30000.0F)->as_number() / 60.0F;
- gamma_stepper_motor->max_rate = THEKERNEL->config->value(gamma_max_rate_checksum)->by_default(30000.0F)->as_number() / 60.0F;
+ alpha_stepper_motor->set_max_rate(THEKERNEL->config->value(alpha_max_rate_checksum)->by_default(30000.0F)->as_number() / 60.0F);
+ beta_stepper_motor->set_max_rate(THEKERNEL->config->value(beta_max_rate_checksum )->by_default(30000.0F)->as_number() / 60.0F);
+ gamma_stepper_motor->set_max_rate(THEKERNEL->config->value(gamma_max_rate_checksum)->by_default(30000.0F)->as_number() / 60.0F);
check_max_actuator_speeds(); // check the configs are sane
actuators.clear();
//this->clearToolOffset();
}
+void Robot::push_state()
+{
+ bool am= this->absolute_mode;
+ bool im= this->inch_mode;
+ saved_state_t s(this->feed_rate, this->seek_rate, am, im);
+ state_stack.push(s);
+}
+
+void Robot::pop_state()
+{
+ if(!state_stack.empty()) {
+ auto s= state_stack.top();
+ state_stack.pop();
+ this->feed_rate= std::get<0>(s);
+ this->seek_rate= std::get<1>(s);
+ this->absolute_mode= std::get<2>(s);
+ this->inch_mode= std::get<3>(s);
+ }
+}
+
// this does a sanity check that actuator speeds do not exceed steps rate capability
// we will override the actuator max_rate if the combination of max_rate and steps/sec exceeds base_stepping_frequency
void Robot::check_max_actuator_speeds()
{
- float step_freq= alpha_stepper_motor->max_rate * alpha_stepper_motor->get_steps_per_mm();
+ float step_freq= alpha_stepper_motor->get_max_rate() * alpha_stepper_motor->get_steps_per_mm();
if(step_freq > THEKERNEL->base_stepping_frequency) {
- alpha_stepper_motor->max_rate= floorf(THEKERNEL->base_stepping_frequency / alpha_stepper_motor->get_steps_per_mm());
+ alpha_stepper_motor->set_max_rate(floorf(THEKERNEL->base_stepping_frequency / alpha_stepper_motor->get_steps_per_mm()));
THEKERNEL->streams->printf("WARNING: alpha_max_rate exceeds base_stepping_frequency * alpha_steps_per_mm: %f, setting to %f\n", step_freq, alpha_stepper_motor->max_rate);
}
- step_freq= beta_stepper_motor->max_rate * beta_stepper_motor->get_steps_per_mm();
+ step_freq= beta_stepper_motor->get_max_rate() * beta_stepper_motor->get_steps_per_mm();
if(step_freq > THEKERNEL->base_stepping_frequency) {
- beta_stepper_motor->max_rate= floorf(THEKERNEL->base_stepping_frequency / beta_stepper_motor->get_steps_per_mm());
+ beta_stepper_motor->set_max_rate(floorf(THEKERNEL->base_stepping_frequency / beta_stepper_motor->get_steps_per_mm()));
THEKERNEL->streams->printf("WARNING: beta_max_rate exceeds base_stepping_frequency * beta_steps_per_mm: %f, setting to %f\n", step_freq, beta_stepper_motor->max_rate);
}
- step_freq= gamma_stepper_motor->max_rate * gamma_stepper_motor->get_steps_per_mm();
+ step_freq= gamma_stepper_motor->get_max_rate() * gamma_stepper_motor->get_steps_per_mm();
if(step_freq > THEKERNEL->base_stepping_frequency) {
- gamma_stepper_motor->max_rate= floorf(THEKERNEL->base_stepping_frequency / gamma_stepper_motor->get_steps_per_mm());
+ gamma_stepper_motor->set_max_rate(floorf(THEKERNEL->base_stepping_frequency / gamma_stepper_motor->get_steps_per_mm()));
THEKERNEL->streams->printf("WARNING: gamma_max_rate exceeds base_stepping_frequency * gamma_steps_per_mm: %f, setting to %f\n", step_freq, gamma_stepper_motor->max_rate);
}
}
-void Robot::on_get_public_data(void *argument)
-{
- PublicDataRequest *pdr = static_cast<PublicDataRequest *>(argument);
-
- if(!pdr->starts_with(robot_checksum)) return;
-
- if(pdr->second_element_is(speed_override_percent_checksum)) {
- static float return_data;
- return_data = 100.0F * 60.0F / seconds_per_minute;
- pdr->set_data_ptr(&return_data);
- pdr->set_taken();
-
- } else if(pdr->second_element_is(current_position_checksum)) {
- static float return_data[3];
- return_data[0] = from_millimeters(this->last_milestone[0]);
- return_data[1] = from_millimeters(this->last_milestone[1]);
- return_data[2] = from_millimeters(this->last_milestone[2]);
-
- pdr->set_data_ptr(&return_data);
- pdr->set_taken();
- }
-}
-
-void Robot::on_set_public_data(void *argument)
-{
- PublicDataRequest *pdr = static_cast<PublicDataRequest *>(argument);
-
- if(!pdr->starts_with(robot_checksum)) return;
-
- if(pdr->second_element_is(speed_override_percent_checksum)) {
- // NOTE do not use this while printing!
- float t = *static_cast<float *>(pdr->get_data_ptr());
- // enforce minimum 10% speed
- if (t < 10.0F) t = 10.0F;
-
- this->seconds_per_minute = t / 0.6F; // t * 60 / 100
- pdr->set_taken();
- } else if(pdr->second_element_is(current_position_checksum)) {
- float *t = static_cast<float *>(pdr->get_data_ptr());
- for (int i = 0; i < 3; i++) {
- this->last_milestone[i] = this->to_millimeters(t[i]);
- }
-
- float actuator_pos[3];
- arm_solution->cartesian_to_actuator(last_milestone, actuator_pos);
- for (int i = 0; i < 3; i++)
- actuators[i]->change_last_milestone(actuator_pos[i]);
-
- pdr->set_taken();
- }
-}
-
//A GCode has been received
//See if the current Gcode line has some orders for us
void Robot::on_gcode_received(void *argument)
//G-letter Gcodes are mostly what the Robot module is interrested in, other modules also catch the gcode event and do stuff accordingly
if( gcode->has_g) {
switch( gcode->g ) {
- case 0: this->motion_mode = MOTION_MODE_SEEK; gcode->mark_as_taken(); break;
- case 1: this->motion_mode = MOTION_MODE_LINEAR; gcode->mark_as_taken(); break;
- case 2: this->motion_mode = MOTION_MODE_CW_ARC; gcode->mark_as_taken(); break;
- case 3: this->motion_mode = MOTION_MODE_CCW_ARC; gcode->mark_as_taken(); break;
- case 17: this->select_plane(X_AXIS, Y_AXIS, Z_AXIS); gcode->mark_as_taken(); break;
- case 18: this->select_plane(X_AXIS, Z_AXIS, Y_AXIS); gcode->mark_as_taken(); break;
- case 19: this->select_plane(Y_AXIS, Z_AXIS, X_AXIS); gcode->mark_as_taken(); break;
- case 20: this->inch_mode = true; gcode->mark_as_taken(); break;
- case 21: this->inch_mode = false; gcode->mark_as_taken(); break;
- case 90: this->absolute_mode = true; gcode->mark_as_taken(); break;
- case 91: this->absolute_mode = false; gcode->mark_as_taken(); break;
+ case 0: this->motion_mode = MOTION_MODE_SEEK; break;
+ case 1: this->motion_mode = MOTION_MODE_LINEAR; break;
+ case 2: this->motion_mode = MOTION_MODE_CW_ARC; break;
+ case 3: this->motion_mode = MOTION_MODE_CCW_ARC; break;
+ case 4: {
+ uint32_t delay_ms= 0;
+ if (gcode->has_letter('P')) {
+ delay_ms= gcode->get_int('P');
+ }
+ if (gcode->has_letter('S')) {
+ delay_ms += gcode->get_int('S') * 1000;
+ }
+ if (delay_ms > 0){
+ // drain queue
+ THEKERNEL->conveyor->wait_for_empty_queue();
+ // wait for specified time
+ uint32_t start= us_ticker_read(); // mbed call
+ while ((us_ticker_read() - start) < delay_ms*1000) {
+ THEKERNEL->call_event(ON_IDLE, this);
+ }
+ }
+ }
+ break;
+ case 17: this->select_plane(X_AXIS, Y_AXIS, Z_AXIS); break;
+ case 18: this->select_plane(X_AXIS, Z_AXIS, Y_AXIS); break;
+ case 19: this->select_plane(Y_AXIS, Z_AXIS, X_AXIS); break;
+ case 20: this->inch_mode = true; break;
+ case 21: this->inch_mode = false; break;
+ case 90: this->absolute_mode = true; break;
+ case 91: this->absolute_mode = false; break;
case 92: {
if(gcode->get_num_args() == 0) {
for (int i = X_AXIS; i <= Z_AXIS; ++i) {
}
}
}
-
- gcode->mark_as_taken();
return;
}
}
gcode->stream->printf("X:%g Y:%g Z:%g F:%g ", actuators[0]->steps_per_mm, actuators[1]->steps_per_mm, actuators[2]->steps_per_mm, seconds_per_minute);
gcode->add_nl = true;
- gcode->mark_as_taken();
check_max_actuator_speeds();
return;
+
case 114: {
- char buf[32];
- int n = snprintf(buf, sizeof(buf), "C: X:%1.3f Y:%1.3f Z:%1.3f",
+ char buf[64];
+ int n = snprintf(buf, sizeof(buf), "C: X:%1.3f Y:%1.3f Z:%1.3f A:%1.3f B:%1.3f C:%1.3f ",
from_millimeters(this->last_milestone[0]),
from_millimeters(this->last_milestone[1]),
- from_millimeters(this->last_milestone[2]));
+ from_millimeters(this->last_milestone[2]),
+ actuators[X_AXIS]->get_current_position(),
+ actuators[Y_AXIS]->get_current_position(),
+ actuators[Z_AXIS]->get_current_position() );
gcode->txt_after_ok.append(buf, n);
- gcode->mark_as_taken();
}
return;
+ case 120: // push state
+ push_state();
+ break;
+
+ case 121: // pop state
+ pop_state();
+ break;
+
case 203: // M203 Set maximum feedrates in mm/sec
if (gcode->has_letter('X'))
this->max_speeds[X_AXIS] = gcode->get_value('X');
if (gcode->has_letter('Z'))
this->max_speeds[Z_AXIS] = gcode->get_value('Z');
if (gcode->has_letter('A'))
- alpha_stepper_motor->max_rate = gcode->get_value('A');
+ alpha_stepper_motor->set_max_rate(gcode->get_value('A'));
if (gcode->has_letter('B'))
- beta_stepper_motor->max_rate = gcode->get_value('B');
+ beta_stepper_motor->set_max_rate(gcode->get_value('B'));
if (gcode->has_letter('C'))
- gamma_stepper_motor->max_rate = gcode->get_value('C');
+ gamma_stepper_motor->set_max_rate(gcode->get_value('C'));
check_max_actuator_speeds();
- gcode->stream->printf("X:%g Y:%g Z:%g A:%g B:%g C:%g ",
- this->max_speeds[X_AXIS], this->max_speeds[Y_AXIS], this->max_speeds[Z_AXIS],
- alpha_stepper_motor->max_rate, beta_stepper_motor->max_rate, gamma_stepper_motor->max_rate);
- gcode->add_nl = true;
- gcode->mark_as_taken();
- break;
+ if(gcode->get_num_args() == 0) {
+ gcode->stream->printf("X:%g Y:%g Z:%g A:%g B:%g C:%g ",
+ this->max_speeds[X_AXIS], this->max_speeds[Y_AXIS], this->max_speeds[Z_AXIS],
+ alpha_stepper_motor->get_max_rate(), beta_stepper_motor->get_max_rate(), gamma_stepper_motor->get_max_rate());
+ gcode->add_nl = true;
+ }
- case 204: // M204 Snnn - set acceleration to nnn, NB only Snnn is currently supported
- gcode->mark_as_taken();
+ break;
+ case 204: // M204 Snnn - set acceleration to nnn, Znnn sets z acceleration
if (gcode->has_letter('S')) {
- // TODO for safety so it applies only to following gcodes, maybe a better way to do this?
- THEKERNEL->conveyor->wait_for_empty_queue();
float acc = gcode->get_value('S'); // mm/s^2
// enforce minimum
if (acc < 1.0F)
acc = 1.0F;
THEKERNEL->planner->acceleration = acc;
}
+ if (gcode->has_letter('Z')) {
+ float acc = gcode->get_value('Z'); // mm/s^2
+ // enforce positive
+ if (acc < 0.0F)
+ acc = 0.0F;
+ THEKERNEL->planner->z_acceleration = acc;
+ }
break;
- case 205: // M205 Xnnn - set junction deviation Snnn - Set minimum planner speed
- gcode->mark_as_taken();
+ case 205: // M205 Xnnn - set junction deviation, Z - set Z junction deviation, Snnn - Set minimum planner speed, Ynnn - set minimum step rate
if (gcode->has_letter('X')) {
float jd = gcode->get_value('X');
// enforce minimum
jd = 0.0F;
THEKERNEL->planner->junction_deviation = jd;
}
+ if (gcode->has_letter('Z')) {
+ float jd = gcode->get_value('Z');
+ // enforce minimum, -1 disables it and uses regular junction deviation
+ if (jd < -1.0F)
+ jd = -1.0F;
+ THEKERNEL->planner->z_junction_deviation = jd;
+ }
if (gcode->has_letter('S')) {
float mps = gcode->get_value('S');
// enforce minimum
mps = 0.0F;
THEKERNEL->planner->minimum_planner_speed = mps;
}
+ if (gcode->has_letter('Y')) {
+ alpha_stepper_motor->default_minimum_actuator_rate = gcode->get_value('Y');
+ }
break;
case 220: // M220 - speed override percentage
- gcode->mark_as_taken();
if (gcode->has_letter('S')) {
float factor = gcode->get_value('S');
// enforce minimum 10% speed
factor = 1000.0F;
seconds_per_minute = 6000.0F / factor;
+ }else{
+ gcode->stream->printf("Speed factor at %6.2f %%\n", 6000.0F / seconds_per_minute);
}
break;
case 400: // wait until all moves are done up to this point
- gcode->mark_as_taken();
THEKERNEL->conveyor->wait_for_empty_queue();
break;
case 500: // M500 saves some volatile settings to config override file
case 503: { // M503 just prints the settings
gcode->stream->printf(";Steps per unit:\nM92 X%1.5f Y%1.5f Z%1.5f\n", actuators[0]->steps_per_mm, actuators[1]->steps_per_mm, actuators[2]->steps_per_mm);
- gcode->stream->printf(";Acceleration mm/sec^2:\nM204 S%1.5f\n", THEKERNEL->planner->acceleration);
- gcode->stream->printf(";X- Junction Deviation, S - Minimum Planner speed:\nM205 X%1.5f S%1.5f\n", THEKERNEL->planner->junction_deviation, THEKERNEL->planner->minimum_planner_speed);
+ gcode->stream->printf(";Acceleration mm/sec^2:\nM204 S%1.5f Z%1.5f\n", THEKERNEL->planner->acceleration, THEKERNEL->planner->z_acceleration);
+ gcode->stream->printf(";X- Junction Deviation, Z- Z junction deviation, S - Minimum Planner speed mm/sec:\nM205 X%1.5f Z%1.5f S%1.5f\n", THEKERNEL->planner->junction_deviation, THEKERNEL->planner->z_junction_deviation, THEKERNEL->planner->minimum_planner_speed);
gcode->stream->printf(";Max feedrates in mm/sec, XYZ cartesian, ABC actuator:\nM203 X%1.5f Y%1.5f Z%1.5f A%1.5f B%1.5f C%1.5f\n",
this->max_speeds[X_AXIS], this->max_speeds[Y_AXIS], this->max_speeds[Z_AXIS],
- alpha_stepper_motor->max_rate, beta_stepper_motor->max_rate, gamma_stepper_motor->max_rate);
+ alpha_stepper_motor->get_max_rate(), beta_stepper_motor->get_max_rate(), gamma_stepper_motor->get_max_rate());
// get or save any arm solution specific optional values
BaseSolution::arm_options_t options;
}
gcode->stream->printf("\n");
}
- gcode->mark_as_taken();
+
break;
}
case 665: { // M665 set optional arm solution variables based on arm solution.
- gcode->mark_as_taken();
- // the parameter args could be any letter except S so ask solution what options it supports
- BaseSolution::arm_options_t options;
+ // the parameter args could be any letter each arm solution only accepts certain ones
+ BaseSolution::arm_options_t options= gcode->get_args();
+ options.erase('S'); // don't include the S
+ options.erase('U'); // don't include the U
+ if(options.size() > 0) {
+ // set the specified options
+ arm_solution->set_optional(options);
+ }
+ options.clear();
if(arm_solution->get_optional(options)) {
+ // foreach optional value
for(auto &i : options) {
- // foreach optional value
- char c = i.first;
- if(gcode->has_letter(c)) { // set new value
- i.second = gcode->get_value(c);
- }
// print all current values of supported options
gcode->stream->printf("%c: %8.4f ", i.first, i.second);
gcode->add_nl = true;
}
- // set the new options
- arm_solution->set_optional(options);
}
- // set delta segments per second, not saved by M500
- if(gcode->has_letter('S')) {
+ if(gcode->has_letter('S')) { // set delta segments per second, not saved by M500
this->delta_segments_per_second = gcode->get_value('S');
+ gcode->stream->printf("Delta segments set to %8.4f segs/sec\n", this->delta_segments_per_second);
+
+ }else if(gcode->has_letter('U')) { // or set mm_per_line_segment, not saved by M500
+ this->mm_per_line_segment = gcode->get_value('U');
+ this->delta_segments_per_second = 0;
+ gcode->stream->printf("mm per line segment set to %8.4f\n", this->mm_per_line_segment);
}
+
break;
}
}
// and continue
void Robot::distance_in_gcode_is_known(Gcode *gcode)
{
-
//If the queue is empty, execute immediatly, otherwise attach to the last added block
THEKERNEL->conveyor->append_gcode(gcode);
}
this->last_milestone[X_AXIS] = x;
this->last_milestone[Y_AXIS] = y;
this->last_milestone[Z_AXIS] = z;
+ this->transformed_last_milestone[X_AXIS] = x;
+ this->transformed_last_milestone[Y_AXIS] = y;
+ this->transformed_last_milestone[Z_AXIS] = z;
float actuator_pos[3];
arm_solution->cartesian_to_actuator(this->last_milestone, actuator_pos);
void Robot::reset_axis_position(float position, int axis)
{
this->last_milestone[axis] = position;
+ this->transformed_last_milestone[axis] = position;
float actuator_pos[3];
arm_solution->cartesian_to_actuator(this->last_milestone, actuator_pos);
actuators[i]->change_last_milestone(actuator_pos[i]);
}
+// Use FK to find out where actuator is and reset lastmilestone to match
+void Robot::reset_position_from_current_actuator_position()
+{
+ float actuator_pos[]= {actuators[X_AXIS]->get_current_position(), actuators[Y_AXIS]->get_current_position(), actuators[Z_AXIS]->get_current_position()};
+ arm_solution->actuator_to_cartesian(actuator_pos, this->last_milestone);
+ memcpy(this->transformed_last_milestone, this->last_milestone, sizeof(this->transformed_last_milestone));
+
+ // now reset actuator correctly, NOTE this may lose a little precision
+ arm_solution->cartesian_to_actuator(this->last_milestone, actuator_pos);
+ for (int i = 0; i < 3; i++)
+ actuators[i]->change_last_milestone(actuator_pos[i]);
+}
// Convert target from millimeters to steps, and append this to the planner
-void Robot::append_milestone( float target[], float rate_mm_s )
+void Robot::append_milestone(Gcode *gcode, float target[], float rate_mm_s)
{
float deltas[3];
float unit_vec[3];
float actuator_pos[3];
- float adj_target[3]; // adjust target for bed leveling
+ float transformed_target[3]; // adjust target for bed compensation
float millimeters_of_travel;
- memcpy(adj_target, target, sizeof(adj_target));
+ // unity transform by default
+ memcpy(transformed_target, target, sizeof(transformed_target));
- // check function pointer and call if set to adjust Z for bed leveling
- if(adjustZfnc) {
- adj_target[Z_AXIS] += adjustZfnc(target[X_AXIS], target[Y_AXIS]);
+ // check function pointer and call if set to transform the target to compensate for bed
+ if(compensationTransform) {
+ // some compensation strategies can transform XYZ, some just change Z
+ compensationTransform(transformed_target);
}
- // find distance moved by each axis, use actual adjusted target
- for (int axis = X_AXIS; axis <= Z_AXIS; axis++)
- deltas[axis] = adj_target[axis] - last_milestone[axis];
+ // find distance moved by each axis, use transformed target from last_transformed_target
+ for (int axis = X_AXIS; axis <= Z_AXIS; axis++){
+ deltas[axis] = transformed_target[axis] - transformed_last_milestone[axis];
+ }
+ // store last transformed
+ memcpy(this->transformed_last_milestone, transformed_target, sizeof(this->transformed_last_milestone));
// Compute how long this move moves, so we can attach it to the block for later use
millimeters_of_travel = sqrtf( powf( deltas[X_AXIS], 2 ) + powf( deltas[Y_AXIS], 2 ) + powf( deltas[Z_AXIS], 2 ) );
}
// find actuator position given cartesian position, use actual adjusted target
- arm_solution->cartesian_to_actuator( adj_target, actuator_pos );
+ arm_solution->cartesian_to_actuator( transformed_target, actuator_pos );
+ float isecs= rate_mm_s / millimeters_of_travel;
// check per-actuator speed limits
for (int actuator = 0; actuator <= 2; actuator++) {
- float actuator_rate = fabs(actuator_pos[actuator] - actuators[actuator]->last_milestone_mm) * rate_mm_s / millimeters_of_travel;
-
- if (actuator_rate > actuators[actuator]->max_rate)
- rate_mm_s *= (actuators[actuator]->max_rate / actuator_rate);
+ float actuator_rate = fabsf(actuator_pos[actuator] - actuators[actuator]->last_milestone_mm) * isecs;
+ if (actuator_rate > actuators[actuator]->get_max_rate()){
+ rate_mm_s *= (actuators[actuator]->get_max_rate() / actuator_rate);
+ isecs= rate_mm_s / millimeters_of_travel;
+ }
}
// Append the block to the planner
// Append a move to the queue ( cutting it into segments if needed )
void Robot::append_line(Gcode *gcode, float target[], float rate_mm_s )
{
-
// Find out the distance for this gcode
- gcode->millimeters_of_travel = powf( target[X_AXIS] - this->last_milestone[X_AXIS], 2 ) + powf( target[Y_AXIS] - this->last_milestone[Y_AXIS], 2 ) + powf( target[Z_AXIS] - this->last_milestone[Z_AXIS], 2 );
+ // NOTE we need to do sqrt here as this setting of millimeters_of_travel is used by extruder and other modules even if there is no XYZ move
+ gcode->millimeters_of_travel = sqrtf(powf( target[X_AXIS] - this->last_milestone[X_AXIS], 2 ) + powf( target[Y_AXIS] - this->last_milestone[Y_AXIS], 2 ) + powf( target[Z_AXIS] - this->last_milestone[Z_AXIS], 2 ));
- // We ignore non-moves ( for example, extruder moves are not XYZ moves )
- if( gcode->millimeters_of_travel < 1e-8F ) {
+ // We ignore non- XYZ moves ( for example, extruder moves are not XYZ moves )
+ if( gcode->millimeters_of_travel < 0.00001F ) {
return;
}
- gcode->millimeters_of_travel = sqrtf(gcode->millimeters_of_travel);
-
// Mark the gcode as having a known distance
this->distance_in_gcode_is_known( gcode );
+ // if we have volumetric limits enabled we calculate the volume for this move and limit the rate if it exceeds the stated limit
+ // Note we need to be using volumetric extrusion for this to work as Ennn is in mm³ not mm
+ // We also check we are not exceeding the E max_speed for the current extruder
+ // We ask Extruder to do all the work, but as Extruder won't even see this gcode until after it has been planned
+ // we need to ask it now passing in the relevant data.
+ // NOTE we need to do this before we segment the line (for deltas)
+ if(gcode->has_letter('E')) {
+ float data[2];
+ data[0]= gcode->get_value('E'); // E target (maybe absolute or relative)
+ data[1]= rate_mm_s / gcode->millimeters_of_travel; // inverted seconds for the move
+ if(PublicData::set_value(extruder_checksum, target_checksum, data)) {
+ rate_mm_s *= data[1];
+ //THEKERNEL->streams->printf("Extruder has changed the rate by %f to %f\n", data[1], rate_mm_s);
+ }
+ }
+
// We cut the line into smaller segments. This is not usefull in a cartesian robot, but necessary for robots with rotational axes.
// In cartesian robot, a high "mm_per_line_segment" setting will prevent waste.
- // In delta robots either mm_per_line_segment can be used OR delta_segments_per_second The latter is more efficient and avoids splitting fast long lines into very small segments, like initial z move to 0, it is what Johanns Marlin delta port does
+ // In delta robots either mm_per_line_segment can be used OR delta_segments_per_second
+ // The latter is more efficient and avoids splitting fast long lines into very small segments, like initial z move to 0, it is what Johanns Marlin delta port does
uint16_t segments;
if(this->delta_segments_per_second > 1.0F) {
// the faster the travel speed the fewer segments needed
// NOTE rate is mm/sec and we take into account any speed override
float seconds = gcode->millimeters_of_travel / rate_mm_s;
- segments = max(1, ceil(this->delta_segments_per_second * seconds));
+ segments = max(1.0F, ceilf(this->delta_segments_per_second * seconds));
// TODO if we are only moving in Z on a delta we don't really need to segment at all
} else {
if(this->mm_per_line_segment == 0.0F) {
segments = 1; // don't split it up
} else {
- segments = ceil( gcode->millimeters_of_travel / this->mm_per_line_segment);
+ segments = ceilf( gcode->millimeters_of_travel / this->mm_per_line_segment);
}
}
// segment 0 is already done - it's the end point of the previous move so we start at segment 1
// We always add another point after this loop so we stop at segments-1, ie i < segments
for (int i = 1; i < segments; i++) {
+ if(THEKERNEL->is_halted()) return; // don't queue any more segments
for(int axis = X_AXIS; axis <= Z_AXIS; axis++ )
segment_end[axis] = last_milestone[axis] + segment_delta[axis];
// Append the end of this segment to the queue
- this->append_milestone(segment_end, rate_mm_s);
+ this->append_milestone(gcode, segment_end, rate_mm_s);
}
}
// Append the end of this full move to the queue
- this->append_milestone(target, rate_mm_s);
+ this->append_milestone(gcode, target, rate_mm_s);
// if adding these blocks didn't start executing, do that now
THEKERNEL->conveyor->ensure_running();
float rt_axis0 = target[this->plane_axis_0] - center_axis0;
float rt_axis1 = target[this->plane_axis_1] - center_axis1;
+ // Patch from GRBL Firmware - Christoph Baumann 04072015
// CCW angle between position and target from circle center. Only one atan2() trig computation required.
- float angular_travel = atan2(r_axis0 * rt_axis1 - r_axis1 * rt_axis0, r_axis0 * rt_axis0 + r_axis1 * rt_axis1);
- if (angular_travel < 0) {
- angular_travel += 2 * M_PI;
- }
- if (is_clockwise) {
- angular_travel -= 2 * M_PI;
+ float angular_travel = atan2(r_axis0*rt_axis1-r_axis1*rt_axis0, r_axis0*rt_axis0+r_axis1*rt_axis1);
+ if (is_clockwise) { // Correct atan2 output per direction
+ if (angular_travel >= -ARC_ANGULAR_TRAVEL_EPSILON) { angular_travel -= 2*M_PI; }
+ } else {
+ if (angular_travel <= ARC_ANGULAR_TRAVEL_EPSILON) { angular_travel += 2*M_PI; }
}
// Find the distance for this gcode
gcode->millimeters_of_travel = hypotf(angular_travel * radius, fabs(linear_travel));
// We don't care about non-XYZ moves ( for example the extruder produces some of those )
- if( gcode->millimeters_of_travel < 0.0001F ) {
+ if( gcode->millimeters_of_travel < 0.00001F ) {
return;
}
this->distance_in_gcode_is_known( gcode );
// Figure out how many segments for this gcode
- uint16_t segments = floor(gcode->millimeters_of_travel / this->mm_per_arc_segment);
+ uint16_t segments = floorf(gcode->millimeters_of_travel / this->mm_per_arc_segment);
float theta_per_segment = angular_travel / segments;
float linear_per_segment = linear_travel / segments;
arc_target[this->plane_axis_2] = this->last_milestone[this->plane_axis_2];
for (i = 1; i < segments; i++) { // Increment (segments-1)
+ if(THEKERNEL->is_halted()) return; // don't queue any more segments
if (count < this->arc_correction ) {
// Apply vector rotation matrix
arc_target[this->plane_axis_2] += linear_per_segment;
// Append this segment to the queue
- this->append_milestone(arc_target, this->feed_rate / seconds_per_minute);
+ this->append_milestone(gcode, arc_target, this->feed_rate / seconds_per_minute);
}
// Ensure last segment arrives at target location.
- this->append_milestone(target, this->feed_rate / seconds_per_minute);
+ this->append_milestone(gcode, target, this->feed_rate / seconds_per_minute);
}
// Do the math for an arc and add it to the queue