| 1 | /* |
| 2 | This file is part of Smoothie (http://smoothieware.org/). The motion control part is heavily based on Grbl (https://github.com/simen/grbl) with additions from Sungeun K. Jeon (https://github.com/chamnit/grbl) |
| 3 | Smoothie is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. |
| 4 | Smoothie is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. |
| 5 | You should have received a copy of the GNU General Public License along with Smoothie. If not, see <http://www.gnu.org/licenses/>. |
| 6 | */ |
| 7 | |
| 8 | #include "libs/Module.h" |
| 9 | #include "libs/Kernel.h" |
| 10 | |
| 11 | #include "Robot.h" |
| 12 | #include "Planner.h" |
| 13 | #include "Conveyor.h" |
| 14 | #include "Pin.h" |
| 15 | #include "StepperMotor.h" |
| 16 | #include "Gcode.h" |
| 17 | #include "PublicDataRequest.h" |
| 18 | #include "PublicData.h" |
| 19 | #include "arm_solutions/BaseSolution.h" |
| 20 | #include "arm_solutions/CartesianSolution.h" |
| 21 | #include "arm_solutions/RotatableCartesianSolution.h" |
| 22 | #include "arm_solutions/LinearDeltaSolution.h" |
| 23 | #include "arm_solutions/RotaryDeltaSolution.h" |
| 24 | #include "arm_solutions/HBotSolution.h" |
| 25 | #include "arm_solutions/CoreXZSolution.h" |
| 26 | #include "arm_solutions/MorganSCARASolution.h" |
| 27 | #include "StepTicker.h" |
| 28 | #include "checksumm.h" |
| 29 | #include "utils.h" |
| 30 | #include "ConfigValue.h" |
| 31 | #include "libs/StreamOutput.h" |
| 32 | #include "StreamOutputPool.h" |
| 33 | #include "ExtruderPublicAccess.h" |
| 34 | #include "GcodeDispatch.h" |
| 35 | #include "ActuatorCoordinates.h" |
| 36 | |
| 37 | #include "mbed.h" // for us_ticker_read() |
| 38 | #include "mri.h" |
| 39 | |
| 40 | #include <fastmath.h> |
| 41 | #include <string> |
| 42 | #include <algorithm> |
| 43 | |
| 44 | #define default_seek_rate_checksum CHECKSUM("default_seek_rate") |
| 45 | #define default_feed_rate_checksum CHECKSUM("default_feed_rate") |
| 46 | #define mm_per_line_segment_checksum CHECKSUM("mm_per_line_segment") |
| 47 | #define delta_segments_per_second_checksum CHECKSUM("delta_segments_per_second") |
| 48 | #define mm_per_arc_segment_checksum CHECKSUM("mm_per_arc_segment") |
| 49 | #define mm_max_arc_error_checksum CHECKSUM("mm_max_arc_error") |
| 50 | #define arc_correction_checksum CHECKSUM("arc_correction") |
| 51 | #define x_axis_max_speed_checksum CHECKSUM("x_axis_max_speed") |
| 52 | #define y_axis_max_speed_checksum CHECKSUM("y_axis_max_speed") |
| 53 | #define z_axis_max_speed_checksum CHECKSUM("z_axis_max_speed") |
| 54 | #define segment_z_moves_checksum CHECKSUM("segment_z_moves") |
| 55 | #define save_g92_checksum CHECKSUM("save_g92") |
| 56 | #define set_g92_checksum CHECKSUM("set_g92") |
| 57 | |
| 58 | // arm solutions |
| 59 | #define arm_solution_checksum CHECKSUM("arm_solution") |
| 60 | #define cartesian_checksum CHECKSUM("cartesian") |
| 61 | #define rotatable_cartesian_checksum CHECKSUM("rotatable_cartesian") |
| 62 | #define rostock_checksum CHECKSUM("rostock") |
| 63 | #define linear_delta_checksum CHECKSUM("linear_delta") |
| 64 | #define rotary_delta_checksum CHECKSUM("rotary_delta") |
| 65 | #define delta_checksum CHECKSUM("delta") |
| 66 | #define hbot_checksum CHECKSUM("hbot") |
| 67 | #define corexy_checksum CHECKSUM("corexy") |
| 68 | #define corexz_checksum CHECKSUM("corexz") |
| 69 | #define kossel_checksum CHECKSUM("kossel") |
| 70 | #define morgan_checksum CHECKSUM("morgan") |
| 71 | |
| 72 | // new-style actuator stuff |
| 73 | #define actuator_checksum CHEKCSUM("actuator") |
| 74 | |
| 75 | #define step_pin_checksum CHECKSUM("step_pin") |
| 76 | #define dir_pin_checksum CHEKCSUM("dir_pin") |
| 77 | #define en_pin_checksum CHECKSUM("en_pin") |
| 78 | |
| 79 | #define steps_per_mm_checksum CHECKSUM("steps_per_mm") |
| 80 | #define max_rate_checksum CHECKSUM("max_rate") |
| 81 | #define acceleration_checksum CHECKSUM("acceleration") |
| 82 | #define z_acceleration_checksum CHECKSUM("z_acceleration") |
| 83 | |
| 84 | #define alpha_checksum CHECKSUM("alpha") |
| 85 | #define beta_checksum CHECKSUM("beta") |
| 86 | #define gamma_checksum CHECKSUM("gamma") |
| 87 | |
| 88 | #define laser_module_default_power_checksum CHECKSUM("laser_module_default_power") |
| 89 | |
| 90 | #define ARC_ANGULAR_TRAVEL_EPSILON 5E-7F // Float (radians) |
| 91 | #define PI 3.14159265358979323846F // force to be float, do not use M_PI |
| 92 | |
| 93 | // 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 |
| 94 | // It takes care of cutting arcs into segments, same thing for line that are too long |
| 95 | |
| 96 | Robot::Robot() |
| 97 | { |
| 98 | this->inch_mode = false; |
| 99 | this->absolute_mode = true; |
| 100 | this->e_absolute_mode = true; |
| 101 | this->select_plane(X_AXIS, Y_AXIS, Z_AXIS); |
| 102 | memset(this->machine_position, 0, sizeof machine_position); |
| 103 | memset(this->compensated_machine_position, 0, sizeof compensated_machine_position); |
| 104 | this->arm_solution = NULL; |
| 105 | seconds_per_minute = 60.0F; |
| 106 | this->clearToolOffset(); |
| 107 | this->compensationTransform = nullptr; |
| 108 | this->get_e_scale_fnc= nullptr; |
| 109 | this->wcs_offsets.fill(wcs_t(0.0F, 0.0F, 0.0F)); |
| 110 | this->g92_offset = wcs_t(0.0F, 0.0F, 0.0F); |
| 111 | this->next_command_is_MCS = false; |
| 112 | this->disable_segmentation= false; |
| 113 | this->disable_arm_solution= false; |
| 114 | this->n_motors= 0; |
| 115 | } |
| 116 | |
| 117 | //Called when the module has just been loaded |
| 118 | void Robot::on_module_loaded() |
| 119 | { |
| 120 | this->register_for_event(ON_GCODE_RECEIVED); |
| 121 | |
| 122 | // Configuration |
| 123 | this->load_config(); |
| 124 | } |
| 125 | |
| 126 | #define ACTUATOR_CHECKSUMS(X) { \ |
| 127 | CHECKSUM(X "_step_pin"), \ |
| 128 | CHECKSUM(X "_dir_pin"), \ |
| 129 | CHECKSUM(X "_en_pin"), \ |
| 130 | CHECKSUM(X "_steps_per_mm"), \ |
| 131 | CHECKSUM(X "_max_rate"), \ |
| 132 | CHECKSUM(X "_acceleration") \ |
| 133 | } |
| 134 | |
| 135 | void Robot::load_config() |
| 136 | { |
| 137 | // Arm solutions are used to convert positions in millimeters into position in steps for each stepper motor. |
| 138 | // While for a cartesian arm solution, this is a simple multiplication, in other, less simple cases, there is some serious math to be done. |
| 139 | // To make adding those solution easier, they have their own, separate object. |
| 140 | // Here we read the config to find out which arm solution to use |
| 141 | if (this->arm_solution) delete this->arm_solution; |
| 142 | int solution_checksum = get_checksum(THEKERNEL->config->value(arm_solution_checksum)->by_default("cartesian")->as_string()); |
| 143 | // Note checksums are not const expressions when in debug mode, so don't use switch |
| 144 | if(solution_checksum == hbot_checksum || solution_checksum == corexy_checksum) { |
| 145 | this->arm_solution = new HBotSolution(THEKERNEL->config); |
| 146 | |
| 147 | } else if(solution_checksum == corexz_checksum) { |
| 148 | this->arm_solution = new CoreXZSolution(THEKERNEL->config); |
| 149 | |
| 150 | } else if(solution_checksum == rostock_checksum || solution_checksum == kossel_checksum || solution_checksum == delta_checksum || solution_checksum == linear_delta_checksum) { |
| 151 | this->arm_solution = new LinearDeltaSolution(THEKERNEL->config); |
| 152 | |
| 153 | } else if(solution_checksum == rotatable_cartesian_checksum) { |
| 154 | this->arm_solution = new RotatableCartesianSolution(THEKERNEL->config); |
| 155 | |
| 156 | } else if(solution_checksum == rotary_delta_checksum) { |
| 157 | this->arm_solution = new RotaryDeltaSolution(THEKERNEL->config); |
| 158 | |
| 159 | } else if(solution_checksum == morgan_checksum) { |
| 160 | this->arm_solution = new MorganSCARASolution(THEKERNEL->config); |
| 161 | |
| 162 | } else if(solution_checksum == cartesian_checksum) { |
| 163 | this->arm_solution = new CartesianSolution(THEKERNEL->config); |
| 164 | |
| 165 | } else { |
| 166 | this->arm_solution = new CartesianSolution(THEKERNEL->config); |
| 167 | } |
| 168 | |
| 169 | this->feed_rate = THEKERNEL->config->value(default_feed_rate_checksum )->by_default( 100.0F)->as_number(); |
| 170 | this->seek_rate = THEKERNEL->config->value(default_seek_rate_checksum )->by_default( 100.0F)->as_number(); |
| 171 | this->mm_per_line_segment = THEKERNEL->config->value(mm_per_line_segment_checksum )->by_default( 0.0F)->as_number(); |
| 172 | this->delta_segments_per_second = THEKERNEL->config->value(delta_segments_per_second_checksum )->by_default(0.0f )->as_number(); |
| 173 | this->mm_per_arc_segment = THEKERNEL->config->value(mm_per_arc_segment_checksum )->by_default( 0.0f)->as_number(); |
| 174 | this->mm_max_arc_error = THEKERNEL->config->value(mm_max_arc_error_checksum )->by_default( 0.01f)->as_number(); |
| 175 | this->arc_correction = THEKERNEL->config->value(arc_correction_checksum )->by_default( 5 )->as_number(); |
| 176 | |
| 177 | // in mm/sec but specified in config as mm/min |
| 178 | this->max_speeds[X_AXIS] = THEKERNEL->config->value(x_axis_max_speed_checksum )->by_default(60000.0F)->as_number() / 60.0F; |
| 179 | this->max_speeds[Y_AXIS] = THEKERNEL->config->value(y_axis_max_speed_checksum )->by_default(60000.0F)->as_number() / 60.0F; |
| 180 | this->max_speeds[Z_AXIS] = THEKERNEL->config->value(z_axis_max_speed_checksum )->by_default( 300.0F)->as_number() / 60.0F; |
| 181 | |
| 182 | this->segment_z_moves = THEKERNEL->config->value(segment_z_moves_checksum )->by_default(true)->as_bool(); |
| 183 | this->save_g92 = THEKERNEL->config->value(save_g92_checksum )->by_default(false)->as_bool(); |
| 184 | string g92 = THEKERNEL->config->value(set_g92_checksum )->by_default("")->as_string(); |
| 185 | if(!g92.empty()) { |
| 186 | // optional setting for a fixed G92 offset |
| 187 | std::vector<float> t= parse_number_list(g92.c_str()); |
| 188 | if(t.size() == 3) { |
| 189 | g92_offset = wcs_t(t[0], t[1], t[2]); |
| 190 | } |
| 191 | } |
| 192 | |
| 193 | // default s value for laser |
| 194 | this->s_value = THEKERNEL->config->value(laser_module_default_power_checksum)->by_default(0.8F)->as_number(); |
| 195 | |
| 196 | // Make our Primary XYZ StepperMotors, and potentially A B C |
| 197 | uint16_t const checksums[][6] = { |
| 198 | ACTUATOR_CHECKSUMS("alpha"), // X |
| 199 | ACTUATOR_CHECKSUMS("beta"), // Y |
| 200 | ACTUATOR_CHECKSUMS("gamma"), // Z |
| 201 | #if MAX_ROBOT_ACTUATORS > 3 |
| 202 | ACTUATOR_CHECKSUMS("delta"), // A |
| 203 | #if MAX_ROBOT_ACTUATORS > 4 |
| 204 | ACTUATOR_CHECKSUMS("epsilon"), // B |
| 205 | #if MAX_ROBOT_ACTUATORS > 5 |
| 206 | ACTUATOR_CHECKSUMS("zeta") // C |
| 207 | #endif |
| 208 | #endif |
| 209 | #endif |
| 210 | }; |
| 211 | |
| 212 | // default acceleration setting, can be overriden with newer per axis settings |
| 213 | this->default_acceleration= THEKERNEL->config->value(acceleration_checksum)->by_default(100.0F )->as_number(); // Acceleration is in mm/s^2 |
| 214 | |
| 215 | // make each motor |
| 216 | for (size_t a = 0; a < MAX_ROBOT_ACTUATORS; a++) { |
| 217 | Pin pins[3]; //step, dir, enable |
| 218 | for (size_t i = 0; i < 3; i++) { |
| 219 | pins[i].from_string(THEKERNEL->config->value(checksums[a][i])->by_default("nc")->as_string())->as_output(); |
| 220 | } |
| 221 | |
| 222 | if(!pins[0].connected() || !pins[1].connected()) { // step and dir must be defined, but enable is optional |
| 223 | if(a <= Z_AXIS) { |
| 224 | THEKERNEL->streams->printf("FATAL: motor %c is not defined in config\n", 'X'+a); |
| 225 | n_motors= a; // we only have this number of motors |
| 226 | return; |
| 227 | } |
| 228 | break; // if any pin is not defined then the axis is not defined (and axis need to be defined in contiguous order) |
| 229 | } |
| 230 | |
| 231 | StepperMotor *sm = new StepperMotor(pins[0], pins[1], pins[2]); |
| 232 | // register this motor (NB This must be 0,1,2) of the actuators array |
| 233 | uint8_t n= register_motor(sm); |
| 234 | if(n != a) { |
| 235 | // this is a fatal error |
| 236 | THEKERNEL->streams->printf("FATAL: motor %d does not match index %d\n", n, a); |
| 237 | return; |
| 238 | } |
| 239 | |
| 240 | actuators[a]->change_steps_per_mm(THEKERNEL->config->value(checksums[a][3])->by_default(a == 2 ? 2560.0F : 80.0F)->as_number()); |
| 241 | actuators[a]->set_max_rate(THEKERNEL->config->value(checksums[a][4])->by_default(30000.0F)->as_number()/60.0F); // it is in mm/min and converted to mm/sec |
| 242 | actuators[a]->set_acceleration(THEKERNEL->config->value(checksums[a][5])->by_default(NAN)->as_number()); // mm/secs² |
| 243 | } |
| 244 | |
| 245 | check_max_actuator_speeds(); // check the configs are sane |
| 246 | |
| 247 | // if we have not specified a z acceleration see if the legacy config was set |
| 248 | if(isnan(actuators[Z_AXIS]->get_acceleration())) { |
| 249 | float acc= THEKERNEL->config->value(z_acceleration_checksum)->by_default(NAN)->as_number(); // disabled by default |
| 250 | if(!isnan(acc)) { |
| 251 | actuators[Z_AXIS]->set_acceleration(acc); |
| 252 | } |
| 253 | } |
| 254 | |
| 255 | // initialise actuator positions to current cartesian position (X0 Y0 Z0) |
| 256 | // so the first move can be correct if homing is not performed |
| 257 | ActuatorCoordinates actuator_pos; |
| 258 | arm_solution->cartesian_to_actuator(machine_position, actuator_pos); |
| 259 | for (size_t i = 0; i < n_motors; i++) |
| 260 | actuators[i]->change_last_milestone(actuator_pos[i]); |
| 261 | |
| 262 | //this->clearToolOffset(); |
| 263 | } |
| 264 | |
| 265 | uint8_t Robot::register_motor(StepperMotor *motor) |
| 266 | { |
| 267 | // register this motor with the step ticker |
| 268 | THEKERNEL->step_ticker->register_motor(motor); |
| 269 | if(n_motors >= k_max_actuators) { |
| 270 | // this is a fatal error |
| 271 | THEKERNEL->streams->printf("FATAL: too many motors, increase k_max_actuators\n"); |
| 272 | __debugbreak(); |
| 273 | } |
| 274 | actuators.push_back(motor); |
| 275 | motor->set_motor_id(n_motors); |
| 276 | return n_motors++; |
| 277 | } |
| 278 | |
| 279 | void Robot::push_state() |
| 280 | { |
| 281 | bool am = this->absolute_mode; |
| 282 | bool em = this->e_absolute_mode; |
| 283 | bool im = this->inch_mode; |
| 284 | saved_state_t s(this->feed_rate, this->seek_rate, am, em, im, current_wcs); |
| 285 | state_stack.push(s); |
| 286 | } |
| 287 | |
| 288 | void Robot::pop_state() |
| 289 | { |
| 290 | if(!state_stack.empty()) { |
| 291 | auto s = state_stack.top(); |
| 292 | state_stack.pop(); |
| 293 | this->feed_rate = std::get<0>(s); |
| 294 | this->seek_rate = std::get<1>(s); |
| 295 | this->absolute_mode = std::get<2>(s); |
| 296 | this->e_absolute_mode = std::get<3>(s); |
| 297 | this->inch_mode = std::get<4>(s); |
| 298 | this->current_wcs = std::get<5>(s); |
| 299 | } |
| 300 | } |
| 301 | |
| 302 | std::vector<Robot::wcs_t> Robot::get_wcs_state() const |
| 303 | { |
| 304 | std::vector<wcs_t> v; |
| 305 | v.push_back(wcs_t(current_wcs, MAX_WCS, 0)); |
| 306 | for(auto& i : wcs_offsets) { |
| 307 | v.push_back(i); |
| 308 | } |
| 309 | v.push_back(g92_offset); |
| 310 | v.push_back(tool_offset); |
| 311 | return v; |
| 312 | } |
| 313 | |
| 314 | void Robot::get_current_machine_position(float *pos) const |
| 315 | { |
| 316 | // get real time current actuator position in mm |
| 317 | ActuatorCoordinates current_position{ |
| 318 | actuators[X_AXIS]->get_current_position(), |
| 319 | actuators[Y_AXIS]->get_current_position(), |
| 320 | actuators[Z_AXIS]->get_current_position() |
| 321 | }; |
| 322 | |
| 323 | // get machine position from the actuator position using FK |
| 324 | arm_solution->actuator_to_cartesian(current_position, pos); |
| 325 | } |
| 326 | |
| 327 | int Robot::print_position(uint8_t subcode, char *buf, size_t bufsize) const |
| 328 | { |
| 329 | // M114.1 is a new way to do this (similar to how GRBL does it). |
| 330 | // it returns the realtime position based on the current step position of the actuators. |
| 331 | // this does require a FK to get a machine position from the actuator position |
| 332 | // and then invert all the transforms to get a workspace position from machine position |
| 333 | // M114 just does it the old way uses machine_position and does inverse transforms to get the requested position |
| 334 | int n = 0; |
| 335 | if(subcode == 0) { // M114 print WCS |
| 336 | wcs_t pos= mcs2wcs(machine_position); |
| 337 | n = snprintf(buf, bufsize, "C: X:%1.4f Y:%1.4f Z:%1.4f", from_millimeters(std::get<X_AXIS>(pos)), from_millimeters(std::get<Y_AXIS>(pos)), from_millimeters(std::get<Z_AXIS>(pos))); |
| 338 | |
| 339 | } else if(subcode == 4) { |
| 340 | // M114.4 print last milestone |
| 341 | n = snprintf(buf, bufsize, "MP: X:%1.4f Y:%1.4f Z:%1.4f", machine_position[X_AXIS], machine_position[Y_AXIS], machine_position[Z_AXIS]); |
| 342 | |
| 343 | } else if(subcode == 5) { |
| 344 | // M114.5 print last machine position (which should be the same as M114.1 if axis are not moving and no level compensation) |
| 345 | // will differ from LMS by the compensation at the current position otherwise |
| 346 | n = snprintf(buf, bufsize, "CMP: X:%1.4f Y:%1.4f Z:%1.4f", compensated_machine_position[X_AXIS], compensated_machine_position[Y_AXIS], compensated_machine_position[Z_AXIS]); |
| 347 | |
| 348 | } else { |
| 349 | // get real time positions |
| 350 | float mpos[3]; |
| 351 | get_current_machine_position(mpos); |
| 352 | |
| 353 | // current_position/mpos includes the compensation transform so we need to get the inverse to get actual position |
| 354 | if(compensationTransform) compensationTransform(mpos, true); // get inverse compensation transform |
| 355 | |
| 356 | if(subcode == 1) { // M114.1 print realtime WCS |
| 357 | wcs_t pos= mcs2wcs(mpos); |
| 358 | n = snprintf(buf, bufsize, "WCS: X:%1.4f Y:%1.4f Z:%1.4f", from_millimeters(std::get<X_AXIS>(pos)), from_millimeters(std::get<Y_AXIS>(pos)), from_millimeters(std::get<Z_AXIS>(pos))); |
| 359 | |
| 360 | } else if(subcode == 2) { // M114.2 print realtime Machine coordinate system |
| 361 | n = snprintf(buf, bufsize, "MCS: X:%1.4f Y:%1.4f Z:%1.4f", mpos[X_AXIS], mpos[Y_AXIS], mpos[Z_AXIS]); |
| 362 | |
| 363 | } else if(subcode == 3) { // M114.3 print realtime actuator position |
| 364 | // get real time current actuator position in mm |
| 365 | ActuatorCoordinates current_position{ |
| 366 | actuators[X_AXIS]->get_current_position(), |
| 367 | actuators[Y_AXIS]->get_current_position(), |
| 368 | actuators[Z_AXIS]->get_current_position() |
| 369 | }; |
| 370 | n = snprintf(buf, bufsize, "APOS: X:%1.4f Y:%1.4f Z:%1.4f", current_position[X_AXIS], current_position[Y_AXIS], current_position[Z_AXIS]); |
| 371 | } |
| 372 | } |
| 373 | |
| 374 | #if MAX_ROBOT_ACTUATORS > 3 |
| 375 | // deal with the ABC axis |
| 376 | for (int i = A_AXIS; i < n_motors; ++i) { |
| 377 | if(actuators[i]->is_extruder()) continue; // don't show an extruder as that will be E |
| 378 | if(subcode == 4) { // M114.4 print last milestone |
| 379 | n += snprintf(&buf[n], bufsize-n, " %c:%1.4f", 'A'+i-A_AXIS, machine_position[i]); |
| 380 | |
| 381 | }else if(subcode == 2 || subcode == 3) { // M114.2/M114.3 print actuator position which is the same as machine position for ABC |
| 382 | // current actuator position |
| 383 | n += snprintf(&buf[n], bufsize-n, " %c:%1.4f", 'A'+i-A_AXIS, actuators[i]->get_current_position()); |
| 384 | } |
| 385 | } |
| 386 | #endif |
| 387 | |
| 388 | return n; |
| 389 | } |
| 390 | |
| 391 | // converts current last milestone (machine position without compensation transform) to work coordinate system (inverse transform) |
| 392 | Robot::wcs_t Robot::mcs2wcs(const Robot::wcs_t& pos) const |
| 393 | { |
| 394 | return std::make_tuple( |
| 395 | std::get<X_AXIS>(pos) - std::get<X_AXIS>(wcs_offsets[current_wcs]) + std::get<X_AXIS>(g92_offset) - std::get<X_AXIS>(tool_offset), |
| 396 | std::get<Y_AXIS>(pos) - std::get<Y_AXIS>(wcs_offsets[current_wcs]) + std::get<Y_AXIS>(g92_offset) - std::get<Y_AXIS>(tool_offset), |
| 397 | std::get<Z_AXIS>(pos) - std::get<Z_AXIS>(wcs_offsets[current_wcs]) + std::get<Z_AXIS>(g92_offset) - std::get<Z_AXIS>(tool_offset) |
| 398 | ); |
| 399 | } |
| 400 | |
| 401 | // this does a sanity check that actuator speeds do not exceed steps rate capability |
| 402 | // we will override the actuator max_rate if the combination of max_rate and steps/sec exceeds base_stepping_frequency |
| 403 | void Robot::check_max_actuator_speeds() |
| 404 | { |
| 405 | for (size_t i = 0; i < n_motors; i++) { |
| 406 | if(actuators[i]->is_extruder()) continue; //extruders are not included in this check |
| 407 | |
| 408 | float step_freq = actuators[i]->get_max_rate() * actuators[i]->get_steps_per_mm(); |
| 409 | if (step_freq > THEKERNEL->base_stepping_frequency) { |
| 410 | actuators[i]->set_max_rate(floorf(THEKERNEL->base_stepping_frequency / actuators[i]->get_steps_per_mm())); |
| 411 | THEKERNEL->streams->printf("WARNING: actuator %d rate exceeds base_stepping_frequency * ..._steps_per_mm: %f, setting to %f\n", i, step_freq, actuators[i]->get_max_rate()); |
| 412 | } |
| 413 | } |
| 414 | } |
| 415 | |
| 416 | //A GCode has been received |
| 417 | //See if the current Gcode line has some orders for us |
| 418 | void Robot::on_gcode_received(void *argument) |
| 419 | { |
| 420 | Gcode *gcode = static_cast<Gcode *>(argument); |
| 421 | |
| 422 | enum MOTION_MODE_T motion_mode= NONE; |
| 423 | |
| 424 | if( gcode->has_g) { |
| 425 | switch( gcode->g ) { |
| 426 | case 0: motion_mode = SEEK; break; |
| 427 | case 1: motion_mode = LINEAR; break; |
| 428 | case 2: motion_mode = CW_ARC; break; |
| 429 | case 3: motion_mode = CCW_ARC; break; |
| 430 | case 4: { // G4 Dwell |
| 431 | uint32_t delay_ms = 0; |
| 432 | if (gcode->has_letter('P')) { |
| 433 | if(THEKERNEL->is_grbl_mode()) { |
| 434 | // in grbl mode (and linuxcnc) P is decimal seconds |
| 435 | float f= gcode->get_value('P'); |
| 436 | delay_ms= f * 1000.0F; |
| 437 | |
| 438 | }else{ |
| 439 | // in reprap P is milliseconds, they always have to be different! |
| 440 | delay_ms = gcode->get_int('P'); |
| 441 | } |
| 442 | } |
| 443 | if (gcode->has_letter('S')) { |
| 444 | delay_ms += gcode->get_int('S') * 1000; |
| 445 | } |
| 446 | if (delay_ms > 0) { |
| 447 | // drain queue |
| 448 | THEKERNEL->conveyor->wait_for_idle(); |
| 449 | // wait for specified time |
| 450 | uint32_t start = us_ticker_read(); // mbed call |
| 451 | while ((us_ticker_read() - start) < delay_ms * 1000) { |
| 452 | THEKERNEL->call_event(ON_IDLE, this); |
| 453 | if(THEKERNEL->is_halted()) return; |
| 454 | } |
| 455 | } |
| 456 | } |
| 457 | break; |
| 458 | |
| 459 | case 10: // G10 L2 [L20] Pn Xn Yn Zn set WCS |
| 460 | if(gcode->has_letter('L') && (gcode->get_int('L') == 2 || gcode->get_int('L') == 20) && gcode->has_letter('P')) { |
| 461 | size_t n = gcode->get_uint('P'); |
| 462 | if(n == 0) n = current_wcs; // set current coordinate system |
| 463 | else --n; |
| 464 | if(n < MAX_WCS) { |
| 465 | float x, y, z; |
| 466 | std::tie(x, y, z) = wcs_offsets[n]; |
| 467 | if(gcode->get_int('L') == 20) { |
| 468 | // this makes the current machine position (less compensation transform) the offset |
| 469 | // get current position in WCS |
| 470 | wcs_t pos= mcs2wcs(machine_position); |
| 471 | |
| 472 | if(gcode->has_letter('X')){ |
| 473 | x -= to_millimeters(gcode->get_value('X')) - std::get<X_AXIS>(pos); |
| 474 | } |
| 475 | |
| 476 | if(gcode->has_letter('Y')){ |
| 477 | y -= to_millimeters(gcode->get_value('Y')) - std::get<Y_AXIS>(pos); |
| 478 | } |
| 479 | if(gcode->has_letter('Z')) { |
| 480 | z -= to_millimeters(gcode->get_value('Z')) - std::get<Z_AXIS>(pos); |
| 481 | } |
| 482 | |
| 483 | } else { |
| 484 | if(absolute_mode) { |
| 485 | // the value is the offset from machine zero |
| 486 | if(gcode->has_letter('X')) x = to_millimeters(gcode->get_value('X')); |
| 487 | if(gcode->has_letter('Y')) y = to_millimeters(gcode->get_value('Y')); |
| 488 | if(gcode->has_letter('Z')) z = to_millimeters(gcode->get_value('Z')); |
| 489 | }else{ |
| 490 | if(gcode->has_letter('X')) x += to_millimeters(gcode->get_value('X')); |
| 491 | if(gcode->has_letter('Y')) y += to_millimeters(gcode->get_value('Y')); |
| 492 | if(gcode->has_letter('Z')) z += to_millimeters(gcode->get_value('Z')); |
| 493 | } |
| 494 | } |
| 495 | wcs_offsets[n] = wcs_t(x, y, z); |
| 496 | } |
| 497 | } |
| 498 | break; |
| 499 | |
| 500 | case 17: this->select_plane(X_AXIS, Y_AXIS, Z_AXIS); break; |
| 501 | case 18: this->select_plane(X_AXIS, Z_AXIS, Y_AXIS); break; |
| 502 | case 19: this->select_plane(Y_AXIS, Z_AXIS, X_AXIS); break; |
| 503 | case 20: this->inch_mode = true; break; |
| 504 | case 21: this->inch_mode = false; break; |
| 505 | |
| 506 | case 54: case 55: case 56: case 57: case 58: case 59: |
| 507 | // select WCS 0-8: G54..G59, G59.1, G59.2, G59.3 |
| 508 | current_wcs = gcode->g - 54; |
| 509 | if(gcode->g == 59 && gcode->subcode > 0) { |
| 510 | current_wcs += gcode->subcode; |
| 511 | if(current_wcs >= MAX_WCS) current_wcs = MAX_WCS - 1; |
| 512 | } |
| 513 | break; |
| 514 | |
| 515 | case 90: this->absolute_mode = true; this->e_absolute_mode = true; break; |
| 516 | case 91: this->absolute_mode = false; this->e_absolute_mode = false; break; |
| 517 | |
| 518 | case 92: { |
| 519 | if(gcode->subcode == 1 || gcode->subcode == 2 || gcode->get_num_args() == 0) { |
| 520 | // reset G92 offsets to 0 |
| 521 | g92_offset = wcs_t(0, 0, 0); |
| 522 | |
| 523 | } else if(gcode->subcode == 3) { |
| 524 | // initialize G92 to the specified values, only used for saving it with M500 |
| 525 | float x= 0, y= 0, z= 0; |
| 526 | if(gcode->has_letter('X')) x= gcode->get_value('X'); |
| 527 | if(gcode->has_letter('Y')) y= gcode->get_value('Y'); |
| 528 | if(gcode->has_letter('Z')) z= gcode->get_value('Z'); |
| 529 | g92_offset = wcs_t(x, y, z); |
| 530 | |
| 531 | } else { |
| 532 | // standard setting of the g92 offsets, making current WCS position whatever the coordinate arguments are |
| 533 | float x, y, z; |
| 534 | std::tie(x, y, z) = g92_offset; |
| 535 | // get current position in WCS |
| 536 | wcs_t pos= mcs2wcs(machine_position); |
| 537 | |
| 538 | // adjust g92 offset to make the current wpos == the value requested |
| 539 | if(gcode->has_letter('X')){ |
| 540 | x += to_millimeters(gcode->get_value('X')) - std::get<X_AXIS>(pos); |
| 541 | } |
| 542 | if(gcode->has_letter('Y')){ |
| 543 | y += to_millimeters(gcode->get_value('Y')) - std::get<Y_AXIS>(pos); |
| 544 | } |
| 545 | if(gcode->has_letter('Z')) { |
| 546 | z += to_millimeters(gcode->get_value('Z')) - std::get<Z_AXIS>(pos); |
| 547 | } |
| 548 | g92_offset = wcs_t(x, y, z); |
| 549 | } |
| 550 | |
| 551 | #if MAX_ROBOT_ACTUATORS > 3 |
| 552 | if(gcode->subcode == 0 && (gcode->has_letter('E') || gcode->get_num_args() == 0)){ |
| 553 | // reset the E position, legacy for 3d Printers to be reprap compatible |
| 554 | // find the selected extruder |
| 555 | int selected_extruder= get_active_extruder(); |
| 556 | if(selected_extruder > 0) { |
| 557 | float e= gcode->has_letter('E') ? gcode->get_value('E') : 0; |
| 558 | machine_position[selected_extruder]= compensated_machine_position[selected_extruder]= e; |
| 559 | actuators[selected_extruder]->change_last_milestone(get_e_scale_fnc ? e*get_e_scale_fnc() : e); |
| 560 | } |
| 561 | } |
| 562 | #endif |
| 563 | |
| 564 | return; |
| 565 | } |
| 566 | } |
| 567 | |
| 568 | } else if( gcode->has_m) { |
| 569 | switch( gcode->m ) { |
| 570 | // case 0: // M0 feed hold, (M0.1 is release feed hold, except we are in feed hold) |
| 571 | // if(THEKERNEL->is_grbl_mode()) THEKERNEL->set_feed_hold(gcode->subcode == 0); |
| 572 | // break; |
| 573 | |
| 574 | case 30: // M30 end of program in grbl mode (otherwise it is delete sdcard file) |
| 575 | if(!THEKERNEL->is_grbl_mode()) break; |
| 576 | // fall through to M2 |
| 577 | case 2: // M2 end of program |
| 578 | current_wcs = 0; |
| 579 | absolute_mode = true; |
| 580 | break; |
| 581 | case 17: |
| 582 | THEKERNEL->call_event(ON_ENABLE, (void*)1); // turn all enable pins on |
| 583 | break; |
| 584 | |
| 585 | case 18: // this allows individual motors to be turned off, no parameters falls through to turn all off |
| 586 | if(gcode->get_num_args() > 0) { |
| 587 | // bitmap of motors to turn off, where bit 1:X, 2:Y, 3:Z, 4:A, 5:B, 6:C |
| 588 | uint32_t bm= 0; |
| 589 | for (int i = 0; i < n_motors; ++i) { |
| 590 | char axis= (i <= Z_AXIS ? 'X'+i : 'A'+(i-3)); |
| 591 | if(gcode->has_letter(axis)) bm |= (0x02<<i); // set appropriate bit |
| 592 | } |
| 593 | // handle E parameter as currently selected extruder ABC |
| 594 | if(gcode->has_letter('E')) { |
| 595 | // find first selected extruder |
| 596 | int i= get_active_extruder(); |
| 597 | if(i > 0) { |
| 598 | bm |= (0x02<<i); // set appropriate bit |
| 599 | } |
| 600 | } |
| 601 | |
| 602 | THEKERNEL->conveyor->wait_for_idle(); |
| 603 | THEKERNEL->call_event(ON_ENABLE, (void *)bm); |
| 604 | break; |
| 605 | } |
| 606 | // fall through |
| 607 | case 84: |
| 608 | THEKERNEL->conveyor->wait_for_idle(); |
| 609 | THEKERNEL->call_event(ON_ENABLE, nullptr); // turn all enable pins off |
| 610 | break; |
| 611 | |
| 612 | case 82: e_absolute_mode= true; break; |
| 613 | case 83: e_absolute_mode= false; break; |
| 614 | |
| 615 | case 92: // M92 - set steps per mm |
| 616 | for (int i = 0; i < n_motors; ++i) { |
| 617 | if(actuators[i]->is_extruder()) continue; //extruders handle this themselves |
| 618 | char axis= (i <= Z_AXIS ? 'X'+i : 'A'+(i-A_AXIS)); |
| 619 | if(gcode->has_letter(axis)) { |
| 620 | actuators[i]->change_steps_per_mm(this->to_millimeters(gcode->get_value(axis))); |
| 621 | } |
| 622 | gcode->stream->printf("%c:%f ", axis, actuators[i]->get_steps_per_mm()); |
| 623 | } |
| 624 | gcode->add_nl = true; |
| 625 | check_max_actuator_speeds(); |
| 626 | return; |
| 627 | |
| 628 | case 114:{ |
| 629 | char buf[128]; |
| 630 | int n= print_position(gcode->subcode, buf, sizeof buf); |
| 631 | if(n > 0) gcode->txt_after_ok.append(buf, n); |
| 632 | return; |
| 633 | } |
| 634 | |
| 635 | case 120: // push state |
| 636 | push_state(); |
| 637 | break; |
| 638 | |
| 639 | case 121: // pop state |
| 640 | pop_state(); |
| 641 | break; |
| 642 | |
| 643 | case 203: // M203 Set maximum feedrates in mm/sec, M203.1 set maximum actuator feedrates |
| 644 | if(gcode->get_num_args() == 0) { |
| 645 | for (size_t i = X_AXIS; i <= Z_AXIS; i++) { |
| 646 | gcode->stream->printf(" %c: %g ", 'X' + i, gcode->subcode == 0 ? this->max_speeds[i] : actuators[i]->get_max_rate()); |
| 647 | } |
| 648 | if(gcode->subcode == 1) { |
| 649 | for (size_t i = A_AXIS; i < n_motors; i++) { |
| 650 | if(actuators[i]->is_extruder()) continue; //extruders handle this themselves |
| 651 | gcode->stream->printf(" %c: %g ", 'A' + i - A_AXIS, actuators[i]->get_max_rate()); |
| 652 | } |
| 653 | } |
| 654 | |
| 655 | gcode->add_nl = true; |
| 656 | |
| 657 | }else{ |
| 658 | for (size_t i = X_AXIS; i <= Z_AXIS; i++) { |
| 659 | if (gcode->has_letter('X' + i)) { |
| 660 | float v= gcode->get_value('X'+i); |
| 661 | if(gcode->subcode == 0) this->max_speeds[i]= v; |
| 662 | else if(gcode->subcode == 1) actuators[i]->set_max_rate(v); |
| 663 | } |
| 664 | } |
| 665 | |
| 666 | if(gcode->subcode == 1) { |
| 667 | // ABC axis only handle actuator max speeds |
| 668 | for (size_t i = A_AXIS; i < n_motors; i++) { |
| 669 | if(actuators[i]->is_extruder()) continue; //extruders handle this themselves |
| 670 | int c= 'A' + i - A_AXIS; |
| 671 | if(gcode->has_letter(c)) { |
| 672 | float v= gcode->get_value(c); |
| 673 | actuators[i]->set_max_rate(v); |
| 674 | } |
| 675 | } |
| 676 | } |
| 677 | |
| 678 | |
| 679 | // this format is deprecated |
| 680 | if(gcode->subcode == 0 && (gcode->has_letter('A') || gcode->has_letter('B') || gcode->has_letter('C'))) { |
| 681 | gcode->stream->printf("NOTE this format is deprecated, Use M203.1 instead\n"); |
| 682 | for (size_t i = X_AXIS; i <= Z_AXIS; i++) { |
| 683 | if (gcode->has_letter('A' + i)) { |
| 684 | float v= gcode->get_value('A'+i); |
| 685 | actuators[i]->set_max_rate(v); |
| 686 | } |
| 687 | } |
| 688 | } |
| 689 | |
| 690 | if(gcode->subcode == 1) check_max_actuator_speeds(); |
| 691 | } |
| 692 | break; |
| 693 | |
| 694 | case 204: // M204 Snnn - set default acceleration to nnn, Xnnn Ynnn Znnn sets axis specific acceleration |
| 695 | if (gcode->has_letter('S')) { |
| 696 | float acc = gcode->get_value('S'); // mm/s^2 |
| 697 | // enforce minimum |
| 698 | if (acc < 1.0F) acc = 1.0F; |
| 699 | this->default_acceleration = acc; |
| 700 | } |
| 701 | for (int i = 0; i < n_motors; ++i) { |
| 702 | if(actuators[i]->is_extruder()) continue; //extruders handle this themselves |
| 703 | char axis= (i <= Z_AXIS ? 'X'+i : 'A'+(i-A_AXIS)); |
| 704 | if(gcode->has_letter(axis)) { |
| 705 | float acc = gcode->get_value(axis); // mm/s^2 |
| 706 | // enforce positive |
| 707 | if (acc <= 0.0F) acc = NAN; |
| 708 | actuators[i]->set_acceleration(acc); |
| 709 | } |
| 710 | } |
| 711 | break; |
| 712 | |
| 713 | case 205: // M205 Xnnn - set junction deviation, Z - set Z junction deviation, Snnn - Set minimum planner speed |
| 714 | if (gcode->has_letter('X')) { |
| 715 | float jd = gcode->get_value('X'); |
| 716 | // enforce minimum |
| 717 | if (jd < 0.0F) |
| 718 | jd = 0.0F; |
| 719 | THEKERNEL->planner->junction_deviation = jd; |
| 720 | } |
| 721 | if (gcode->has_letter('Z')) { |
| 722 | float jd = gcode->get_value('Z'); |
| 723 | // enforce minimum, -1 disables it and uses regular junction deviation |
| 724 | if (jd <= -1.0F) |
| 725 | jd = NAN; |
| 726 | THEKERNEL->planner->z_junction_deviation = jd; |
| 727 | } |
| 728 | if (gcode->has_letter('S')) { |
| 729 | float mps = gcode->get_value('S'); |
| 730 | // enforce minimum |
| 731 | if (mps < 0.0F) |
| 732 | mps = 0.0F; |
| 733 | THEKERNEL->planner->minimum_planner_speed = mps; |
| 734 | } |
| 735 | break; |
| 736 | |
| 737 | case 220: // M220 - speed override percentage |
| 738 | if (gcode->has_letter('S')) { |
| 739 | float factor = gcode->get_value('S'); |
| 740 | // enforce minimum 10% speed |
| 741 | if (factor < 10.0F) |
| 742 | factor = 10.0F; |
| 743 | // enforce maximum 10x speed |
| 744 | if (factor > 1000.0F) |
| 745 | factor = 1000.0F; |
| 746 | |
| 747 | seconds_per_minute = 6000.0F / factor; |
| 748 | } else { |
| 749 | gcode->stream->printf("Speed factor at %6.2f %%\n", 6000.0F / seconds_per_minute); |
| 750 | } |
| 751 | break; |
| 752 | |
| 753 | case 400: // wait until all moves are done up to this point |
| 754 | THEKERNEL->conveyor->wait_for_idle(); |
| 755 | break; |
| 756 | |
| 757 | case 500: // M500 saves some volatile settings to config override file |
| 758 | case 503: { // M503 just prints the settings |
| 759 | gcode->stream->printf(";Steps per unit:\nM92 "); |
| 760 | for (int i = 0; i < n_motors; ++i) { |
| 761 | if(actuators[i]->is_extruder()) continue; //extruders handle this themselves |
| 762 | char axis= (i <= Z_AXIS ? 'X'+i : 'A'+(i-A_AXIS)); |
| 763 | gcode->stream->printf("%c%1.5f ", axis, actuators[i]->get_steps_per_mm()); |
| 764 | } |
| 765 | gcode->stream->printf("\n"); |
| 766 | |
| 767 | // only print if not NAN |
| 768 | gcode->stream->printf(";Acceleration mm/sec^2:\nM204 S%1.5f ", default_acceleration); |
| 769 | for (int i = 0; i < n_motors; ++i) { |
| 770 | if(actuators[i]->is_extruder()) continue; // extruders handle this themselves |
| 771 | char axis= (i <= Z_AXIS ? 'X'+i : 'A'+(i-A_AXIS)); |
| 772 | if(!isnan(actuators[i]->get_acceleration())) gcode->stream->printf("%c%1.5f ", axis, actuators[i]->get_acceleration()); |
| 773 | } |
| 774 | gcode->stream->printf("\n"); |
| 775 | |
| 776 | 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, isnan(THEKERNEL->planner->z_junction_deviation)?-1:THEKERNEL->planner->z_junction_deviation, THEKERNEL->planner->minimum_planner_speed); |
| 777 | |
| 778 | gcode->stream->printf(";Max cartesian feedrates in mm/sec:\nM203 X%1.5f Y%1.5f Z%1.5f\n", this->max_speeds[X_AXIS], this->max_speeds[Y_AXIS], this->max_speeds[Z_AXIS]); |
| 779 | |
| 780 | gcode->stream->printf(";Max actuator feedrates in mm/sec:\nM203.1 "); |
| 781 | for (int i = 0; i < n_motors; ++i) { |
| 782 | if(actuators[i]->is_extruder()) continue; // extruders handle this themselves |
| 783 | char axis= (i <= Z_AXIS ? 'X'+i : 'A'+(i-A_AXIS)); |
| 784 | gcode->stream->printf("%c%1.5f ", axis, actuators[i]->get_max_rate()); |
| 785 | } |
| 786 | gcode->stream->printf("\n"); |
| 787 | |
| 788 | // get or save any arm solution specific optional values |
| 789 | BaseSolution::arm_options_t options; |
| 790 | if(arm_solution->get_optional(options) && !options.empty()) { |
| 791 | gcode->stream->printf(";Optional arm solution specific settings:\nM665"); |
| 792 | for(auto &i : options) { |
| 793 | gcode->stream->printf(" %c%1.4f", i.first, i.second); |
| 794 | } |
| 795 | gcode->stream->printf("\n"); |
| 796 | } |
| 797 | |
| 798 | // save wcs_offsets and current_wcs |
| 799 | // TODO this may need to be done whenever they change to be compliant |
| 800 | gcode->stream->printf(";WCS settings\n"); |
| 801 | gcode->stream->printf("%s\n", wcs2gcode(current_wcs).c_str()); |
| 802 | int n = 1; |
| 803 | for(auto &i : wcs_offsets) { |
| 804 | if(i != wcs_t(0, 0, 0)) { |
| 805 | float x, y, z; |
| 806 | std::tie(x, y, z) = i; |
| 807 | gcode->stream->printf("G10 L2 P%d X%f Y%f Z%f ; %s\n", n, x, y, z, wcs2gcode(n-1).c_str()); |
| 808 | } |
| 809 | ++n; |
| 810 | } |
| 811 | if(save_g92) { |
| 812 | // linuxcnc saves G92, so we do too if configured, default is to not save to maintain backward compatibility |
| 813 | // also it needs to be used to set Z0 on rotary deltas as M206/306 can't be used, so saving it is necessary in that case |
| 814 | if(g92_offset != wcs_t(0, 0, 0)) { |
| 815 | float x, y, z; |
| 816 | std::tie(x, y, z) = g92_offset; |
| 817 | gcode->stream->printf("G92.3 X%f Y%f Z%f\n", x, y, z); // sets G92 to the specified values |
| 818 | } |
| 819 | } |
| 820 | } |
| 821 | break; |
| 822 | |
| 823 | case 665: { // M665 set optional arm solution variables based on arm solution. |
| 824 | // the parameter args could be any letter each arm solution only accepts certain ones |
| 825 | BaseSolution::arm_options_t options = gcode->get_args(); |
| 826 | options.erase('S'); // don't include the S |
| 827 | options.erase('U'); // don't include the U |
| 828 | if(options.size() > 0) { |
| 829 | // set the specified options |
| 830 | arm_solution->set_optional(options); |
| 831 | } |
| 832 | options.clear(); |
| 833 | if(arm_solution->get_optional(options)) { |
| 834 | // foreach optional value |
| 835 | for(auto &i : options) { |
| 836 | // print all current values of supported options |
| 837 | gcode->stream->printf("%c: %8.4f ", i.first, i.second); |
| 838 | gcode->add_nl = true; |
| 839 | } |
| 840 | } |
| 841 | |
| 842 | if(gcode->has_letter('S')) { // set delta segments per second, not saved by M500 |
| 843 | this->delta_segments_per_second = gcode->get_value('S'); |
| 844 | gcode->stream->printf("Delta segments set to %8.4f segs/sec\n", this->delta_segments_per_second); |
| 845 | |
| 846 | } else if(gcode->has_letter('U')) { // or set mm_per_line_segment, not saved by M500 |
| 847 | this->mm_per_line_segment = gcode->get_value('U'); |
| 848 | this->delta_segments_per_second = 0; |
| 849 | gcode->stream->printf("mm per line segment set to %8.4f\n", this->mm_per_line_segment); |
| 850 | } |
| 851 | |
| 852 | break; |
| 853 | } |
| 854 | } |
| 855 | } |
| 856 | |
| 857 | if( motion_mode != NONE) { |
| 858 | is_g123= motion_mode != SEEK; |
| 859 | process_move(gcode, motion_mode); |
| 860 | |
| 861 | }else{ |
| 862 | is_g123= false; |
| 863 | } |
| 864 | |
| 865 | next_command_is_MCS = false; // must be on same line as G0 or G1 |
| 866 | } |
| 867 | |
| 868 | int Robot::get_active_extruder() const |
| 869 | { |
| 870 | for (int i = E_AXIS; i < n_motors; ++i) { |
| 871 | // find first selected extruder |
| 872 | if(actuators[i]->is_extruder() && actuators[i]->is_selected()) return i; |
| 873 | } |
| 874 | return 0; |
| 875 | } |
| 876 | |
| 877 | // process a G0/G1/G2/G3 |
| 878 | void Robot::process_move(Gcode *gcode, enum MOTION_MODE_T motion_mode) |
| 879 | { |
| 880 | // we have a G0/G1/G2/G3 so extract parameters and apply offsets to get machine coordinate target |
| 881 | // get XYZ and one E (which goes to the selected extruder) |
| 882 | float param[4]{NAN, NAN, NAN, NAN}; |
| 883 | |
| 884 | // process primary axis |
| 885 | for(int i= X_AXIS; i <= Z_AXIS; ++i) { |
| 886 | char letter= 'X'+i; |
| 887 | if( gcode->has_letter(letter) ) { |
| 888 | param[i] = this->to_millimeters(gcode->get_value(letter)); |
| 889 | } |
| 890 | } |
| 891 | |
| 892 | float offset[3]{0,0,0}; |
| 893 | for(char letter = 'I'; letter <= 'K'; letter++) { |
| 894 | if( gcode->has_letter(letter) ) { |
| 895 | offset[letter - 'I'] = this->to_millimeters(gcode->get_value(letter)); |
| 896 | } |
| 897 | } |
| 898 | |
| 899 | // calculate target in machine coordinates (less compensation transform which needs to be done after segmentation) |
| 900 | float target[n_motors]; |
| 901 | memcpy(target, machine_position, n_motors*sizeof(float)); |
| 902 | |
| 903 | if(!next_command_is_MCS) { |
| 904 | if(this->absolute_mode) { |
| 905 | // apply wcs offsets and g92 offset and tool offset |
| 906 | if(!isnan(param[X_AXIS])) { |
| 907 | target[X_AXIS]= param[X_AXIS] + std::get<X_AXIS>(wcs_offsets[current_wcs]) - std::get<X_AXIS>(g92_offset) + std::get<X_AXIS>(tool_offset); |
| 908 | } |
| 909 | |
| 910 | if(!isnan(param[Y_AXIS])) { |
| 911 | target[Y_AXIS]= param[Y_AXIS] + std::get<Y_AXIS>(wcs_offsets[current_wcs]) - std::get<Y_AXIS>(g92_offset) + std::get<Y_AXIS>(tool_offset); |
| 912 | } |
| 913 | |
| 914 | if(!isnan(param[Z_AXIS])) { |
| 915 | target[Z_AXIS]= param[Z_AXIS] + std::get<Z_AXIS>(wcs_offsets[current_wcs]) - std::get<Z_AXIS>(g92_offset) + std::get<Z_AXIS>(tool_offset); |
| 916 | } |
| 917 | |
| 918 | }else{ |
| 919 | // they are deltas from the machine_position if specified |
| 920 | for(int i= X_AXIS; i <= Z_AXIS; ++i) { |
| 921 | if(!isnan(param[i])) target[i] = param[i] + machine_position[i]; |
| 922 | } |
| 923 | } |
| 924 | |
| 925 | }else{ |
| 926 | // already in machine coordinates, we do not add tool offset for that |
| 927 | for(int i= X_AXIS; i <= Z_AXIS; ++i) { |
| 928 | if(!isnan(param[i])) target[i] = param[i]; |
| 929 | } |
| 930 | } |
| 931 | |
| 932 | float delta_e= NAN; |
| 933 | |
| 934 | #if MAX_ROBOT_ACTUATORS > 3 |
| 935 | // process extruder parameters, for active extruder only (only one active extruder at a time) |
| 936 | int selected_extruder= 0; |
| 937 | if(gcode->has_letter('E')) { |
| 938 | selected_extruder= get_active_extruder(); |
| 939 | param[E_AXIS]= gcode->get_value('E'); |
| 940 | } |
| 941 | |
| 942 | // do E for the selected extruder |
| 943 | if(selected_extruder > 0 && !isnan(param[E_AXIS])) { |
| 944 | if(this->e_absolute_mode) { |
| 945 | target[selected_extruder]= param[E_AXIS]; |
| 946 | delta_e= target[selected_extruder] - machine_position[selected_extruder]; |
| 947 | }else{ |
| 948 | delta_e= param[E_AXIS]; |
| 949 | target[selected_extruder] = delta_e + machine_position[selected_extruder]; |
| 950 | } |
| 951 | } |
| 952 | |
| 953 | // process ABC axis, this is mutually exclusive to using E for an extruder, so if E is used and A then the results are undefined |
| 954 | for (int i = A_AXIS; i < n_motors; ++i) { |
| 955 | char letter= 'A'+i-A_AXIS; |
| 956 | if(gcode->has_letter(letter)) { |
| 957 | float p= gcode->get_value(letter); |
| 958 | if(this->absolute_mode) { |
| 959 | target[i]= p; |
| 960 | }else{ |
| 961 | target[i]= p + machine_position[i]; |
| 962 | } |
| 963 | } |
| 964 | } |
| 965 | #endif |
| 966 | |
| 967 | if( gcode->has_letter('F') ) { |
| 968 | if( motion_mode == SEEK ) |
| 969 | this->seek_rate = this->to_millimeters( gcode->get_value('F') ); |
| 970 | else |
| 971 | this->feed_rate = this->to_millimeters( gcode->get_value('F') ); |
| 972 | } |
| 973 | |
| 974 | // S is modal When specified on a G0/1/2/3 command |
| 975 | if(gcode->has_letter('S')) s_value= gcode->get_value('S'); |
| 976 | |
| 977 | bool moved= false; |
| 978 | |
| 979 | // Perform any physical actions |
| 980 | switch(motion_mode) { |
| 981 | case NONE: break; |
| 982 | |
| 983 | case SEEK: |
| 984 | moved= this->append_line(gcode, target, this->seek_rate / seconds_per_minute, delta_e ); |
| 985 | break; |
| 986 | |
| 987 | case LINEAR: |
| 988 | moved= this->append_line(gcode, target, this->feed_rate / seconds_per_minute, delta_e ); |
| 989 | break; |
| 990 | |
| 991 | case CW_ARC: |
| 992 | case CCW_ARC: |
| 993 | // Note arcs are not currently supported by extruder based machines, as 3D slicers do not use arcs (G2/G3) |
| 994 | moved= this->compute_arc(gcode, offset, target, motion_mode); |
| 995 | break; |
| 996 | } |
| 997 | |
| 998 | if(moved) { |
| 999 | // set machine_position to the calculated target |
| 1000 | memcpy(machine_position, target, n_motors*sizeof(float)); |
| 1001 | } |
| 1002 | } |
| 1003 | |
| 1004 | // reset the machine position for all axis. Used for homing. |
| 1005 | // after homing we supply the cartesian coordinates that the head is at when homed, |
| 1006 | // however for Z this is the compensated machine position (if enabled) |
| 1007 | // So we need to apply the inverse compensation transform to the supplied coordinates to get the correct machine position |
| 1008 | // this will make the results from M114 and ? consistent after homing. |
| 1009 | // This works for cases where the Z endstop is fixed on the Z actuator and is the same regardless of where XY are. |
| 1010 | void Robot::reset_axis_position(float x, float y, float z) |
| 1011 | { |
| 1012 | // set both the same initially |
| 1013 | compensated_machine_position[X_AXIS]= machine_position[X_AXIS] = x; |
| 1014 | compensated_machine_position[Y_AXIS]= machine_position[Y_AXIS] = y; |
| 1015 | compensated_machine_position[Z_AXIS]= machine_position[Z_AXIS] = z; |
| 1016 | |
| 1017 | if(compensationTransform) { |
| 1018 | // apply inverse transform to get machine_position |
| 1019 | compensationTransform(machine_position, true); |
| 1020 | } |
| 1021 | |
| 1022 | // now set the actuator positions based on the supplied compensated position |
| 1023 | ActuatorCoordinates actuator_pos; |
| 1024 | arm_solution->cartesian_to_actuator(this->compensated_machine_position, actuator_pos); |
| 1025 | for (size_t i = X_AXIS; i <= Z_AXIS; i++) |
| 1026 | actuators[i]->change_last_milestone(actuator_pos[i]); |
| 1027 | } |
| 1028 | |
| 1029 | // Reset the position for an axis (used in homing, and to reset extruder after suspend) |
| 1030 | void Robot::reset_axis_position(float position, int axis) |
| 1031 | { |
| 1032 | compensated_machine_position[axis] = position; |
| 1033 | if(axis <= Z_AXIS) { |
| 1034 | reset_axis_position(compensated_machine_position[X_AXIS], compensated_machine_position[Y_AXIS], compensated_machine_position[Z_AXIS]); |
| 1035 | |
| 1036 | #if MAX_ROBOT_ACTUATORS > 3 |
| 1037 | }else if(axis < n_motors) { |
| 1038 | // ABC and/or extruders need to be set as there is no arm solution for them |
| 1039 | machine_position[axis]= compensated_machine_position[axis]= position; |
| 1040 | actuators[axis]->change_last_milestone(machine_position[axis]); |
| 1041 | #endif |
| 1042 | } |
| 1043 | } |
| 1044 | |
| 1045 | // similar to reset_axis_position but directly sets the actuator positions in actuators units (eg mm for cartesian, degrees for rotary delta) |
| 1046 | // then sets the axis positions to match. currently only called from Endstops.cpp and RotaryDeltaCalibration.cpp |
| 1047 | void Robot::reset_actuator_position(const ActuatorCoordinates &ac) |
| 1048 | { |
| 1049 | for (size_t i = X_AXIS; i <= Z_AXIS; i++) { |
| 1050 | if(!isnan(ac[i])) actuators[i]->change_last_milestone(ac[i]); |
| 1051 | } |
| 1052 | |
| 1053 | // now correct axis positions then recorrect actuator to account for rounding |
| 1054 | reset_position_from_current_actuator_position(); |
| 1055 | } |
| 1056 | |
| 1057 | // Use FK to find out where actuator is and reset to match |
| 1058 | // TODO maybe we should only reset axis that are being homed unless this is due to a ON_HALT |
| 1059 | void Robot::reset_position_from_current_actuator_position() |
| 1060 | { |
| 1061 | ActuatorCoordinates actuator_pos; |
| 1062 | for (size_t i = X_AXIS; i < n_motors; i++) { |
| 1063 | // NOTE actuator::current_position is curently NOT the same as actuator::machine_position after an abrupt abort |
| 1064 | actuator_pos[i] = actuators[i]->get_current_position(); |
| 1065 | } |
| 1066 | |
| 1067 | // discover machine position from where actuators actually are |
| 1068 | arm_solution->actuator_to_cartesian(actuator_pos, compensated_machine_position); |
| 1069 | memcpy(machine_position, compensated_machine_position, sizeof machine_position); |
| 1070 | |
| 1071 | // compensated_machine_position includes the compensation transform so we need to get the inverse to get actual machine_position |
| 1072 | if(compensationTransform) compensationTransform(machine_position, true); // get inverse compensation transform |
| 1073 | |
| 1074 | // now reset actuator::machine_position, NOTE this may lose a little precision as FK is not always entirely accurate. |
| 1075 | // NOTE This is required to sync the machine position with the actuator position, we do a somewhat redundant cartesian_to_actuator() call |
| 1076 | // to get everything in perfect sync. |
| 1077 | arm_solution->cartesian_to_actuator(compensated_machine_position, actuator_pos); |
| 1078 | for (size_t i = X_AXIS; i <= Z_AXIS; i++) { |
| 1079 | actuators[i]->change_last_milestone(actuator_pos[i]); |
| 1080 | } |
| 1081 | |
| 1082 | // Handle extruders and/or ABC axis |
| 1083 | #if MAX_ROBOT_ACTUATORS > 3 |
| 1084 | for (int i = A_AXIS; i < n_motors; i++) { |
| 1085 | // ABC and/or extruders just need to set machine_position and compensated_machine_position |
| 1086 | float ap= actuator_pos[i]; |
| 1087 | if(actuators[i]->is_extruder() && get_e_scale_fnc) ap /= get_e_scale_fnc(); // inverse E scale if there is one and this is an extruder |
| 1088 | machine_position[i]= compensated_machine_position[i]= ap; |
| 1089 | actuators[i]->change_last_milestone(actuator_pos[i]); // this updates the last_milestone in the actuator |
| 1090 | } |
| 1091 | #endif |
| 1092 | } |
| 1093 | |
| 1094 | // Convert target (in machine coordinates) to machine_position, then convert to actuator position and append this to the planner |
| 1095 | // target is in machine coordinates without the compensation transform, however we save a compensated_machine_position that includes |
| 1096 | // all transforms and is what we actually convert to actuator positions |
| 1097 | bool Robot::append_milestone(const float target[], float rate_mm_s) |
| 1098 | { |
| 1099 | float deltas[n_motors]; |
| 1100 | float transformed_target[n_motors]; // adjust target for bed compensation |
| 1101 | float unit_vec[N_PRIMARY_AXIS]; |
| 1102 | |
| 1103 | // unity transform by default |
| 1104 | memcpy(transformed_target, target, n_motors*sizeof(float)); |
| 1105 | |
| 1106 | // check function pointer and call if set to transform the target to compensate for bed |
| 1107 | if(compensationTransform) { |
| 1108 | // some compensation strategies can transform XYZ, some just change Z |
| 1109 | compensationTransform(transformed_target, false); |
| 1110 | } |
| 1111 | |
| 1112 | bool move= false; |
| 1113 | float sos= 0; // sum of squares for just primary axis (XYZ usually) |
| 1114 | |
| 1115 | // find distance moved by each axis, use transformed target from the current compensated machine position |
| 1116 | for (size_t i = 0; i < n_motors; i++) { |
| 1117 | deltas[i] = transformed_target[i] - compensated_machine_position[i]; |
| 1118 | if(deltas[i] == 0) continue; |
| 1119 | // at least one non zero delta |
| 1120 | move = true; |
| 1121 | if(i < N_PRIMARY_AXIS) { |
| 1122 | sos += powf(deltas[i], 2); |
| 1123 | } |
| 1124 | } |
| 1125 | |
| 1126 | // nothing moved |
| 1127 | if(!move) return false; |
| 1128 | |
| 1129 | // see if this is a primary axis move or not |
| 1130 | bool auxilliary_move= true; |
| 1131 | for (int i = 0; i < N_PRIMARY_AXIS; ++i) { |
| 1132 | if(deltas[i] != 0) { |
| 1133 | auxilliary_move= false; |
| 1134 | break; |
| 1135 | } |
| 1136 | } |
| 1137 | |
| 1138 | // total movement, use XYZ if a primary axis otherwise we calculate distance for E after scaling to mm |
| 1139 | float distance= auxilliary_move ? 0 : sqrtf(sos); |
| 1140 | |
| 1141 | // it is unlikely but we need to protect against divide by zero, so ignore insanely small moves here |
| 1142 | // as the last milestone won't be updated we do not actually lose any moves as they will be accounted for in the next move |
| 1143 | if(!auxilliary_move && distance < 0.00001F) return false; |
| 1144 | |
| 1145 | |
| 1146 | if(!auxilliary_move) { |
| 1147 | for (size_t i = X_AXIS; i < N_PRIMARY_AXIS; i++) { |
| 1148 | // find distance unit vector for primary axis only |
| 1149 | unit_vec[i] = deltas[i] / distance; |
| 1150 | |
| 1151 | // Do not move faster than the configured cartesian limits for XYZ |
| 1152 | if ( max_speeds[i] > 0 ) { |
| 1153 | float axis_speed = fabsf(unit_vec[i] * rate_mm_s); |
| 1154 | |
| 1155 | if (axis_speed > max_speeds[i]) |
| 1156 | rate_mm_s *= ( max_speeds[i] / axis_speed ); |
| 1157 | } |
| 1158 | } |
| 1159 | } |
| 1160 | |
| 1161 | // find actuator position given the machine position, use actual adjusted target |
| 1162 | ActuatorCoordinates actuator_pos; |
| 1163 | if(!disable_arm_solution) { |
| 1164 | arm_solution->cartesian_to_actuator( transformed_target, actuator_pos ); |
| 1165 | |
| 1166 | }else{ |
| 1167 | // basically the same as cartesian, would be used for special homing situations like for scara |
| 1168 | for (size_t i = X_AXIS; i <= Z_AXIS; i++) { |
| 1169 | actuator_pos[i] = transformed_target[i]; |
| 1170 | } |
| 1171 | } |
| 1172 | |
| 1173 | #if MAX_ROBOT_ACTUATORS > 3 |
| 1174 | sos= 0; |
| 1175 | // for the extruders just copy the position, and possibly scale it from mm³ to mm |
| 1176 | for (size_t i = E_AXIS; i < n_motors; i++) { |
| 1177 | actuator_pos[i]= transformed_target[i]; |
| 1178 | if(actuators[i]->is_extruder() && get_e_scale_fnc) { |
| 1179 | // NOTE this relies on the fact only one extruder is active at a time |
| 1180 | // scale for volumetric or flow rate |
| 1181 | // TODO is this correct? scaling the absolute target? what if the scale changes? |
| 1182 | // for volumetric it basically converts mm³ to mm, but what about flow rate? |
| 1183 | actuator_pos[i] *= get_e_scale_fnc(); |
| 1184 | } |
| 1185 | if(auxilliary_move) { |
| 1186 | // for E only moves we need to use the scaled E to calculate the distance |
| 1187 | sos += powf(actuator_pos[i] - actuators[i]->get_last_milestone(), 2); |
| 1188 | } |
| 1189 | } |
| 1190 | if(auxilliary_move) { |
| 1191 | distance= sqrtf(sos); // distance in mm of the e move |
| 1192 | if(distance < 0.00001F) return false; |
| 1193 | } |
| 1194 | #endif |
| 1195 | |
| 1196 | // use default acceleration to start with |
| 1197 | float acceleration = default_acceleration; |
| 1198 | |
| 1199 | float isecs = rate_mm_s / distance; |
| 1200 | |
| 1201 | // check per-actuator speed limits |
| 1202 | for (size_t actuator = 0; actuator < n_motors; actuator++) { |
| 1203 | float d = fabsf(actuator_pos[actuator] - actuators[actuator]->get_last_milestone()); |
| 1204 | if(d == 0 || !actuators[actuator]->is_selected()) continue; // no movement for this actuator |
| 1205 | |
| 1206 | float actuator_rate= d * isecs; |
| 1207 | if (actuator_rate > actuators[actuator]->get_max_rate()) { |
| 1208 | rate_mm_s *= (actuators[actuator]->get_max_rate() / actuator_rate); |
| 1209 | isecs = rate_mm_s / distance; |
| 1210 | } |
| 1211 | |
| 1212 | // adjust acceleration to lowest found, for now just primary axis unless it is an auxiliary move |
| 1213 | // TODO we may need to do all of them, check E won't limit XYZ.. it does on long E moves, but not checking it could exceed the E acceleration. |
| 1214 | if(auxilliary_move || actuator < N_PRIMARY_AXIS) { |
| 1215 | float ma = actuators[actuator]->get_acceleration(); // in mm/sec² |
| 1216 | if(!isnan(ma)) { // if axis does not have acceleration set then it uses the default_acceleration |
| 1217 | float ca = fabsf((d/distance) * acceleration); |
| 1218 | if (ca > ma) { |
| 1219 | acceleration *= ( ma / ca ); |
| 1220 | } |
| 1221 | } |
| 1222 | } |
| 1223 | } |
| 1224 | |
| 1225 | // Append the block to the planner |
| 1226 | // NOTE that distance here should be either the distance travelled by the XYZ axis, or the E mm travel if a solo E move |
| 1227 | if(THEKERNEL->planner->append_block( actuator_pos, n_motors, rate_mm_s, distance, auxilliary_move ? nullptr : unit_vec, acceleration, s_value, is_g123)) { |
| 1228 | // this is the new compensated machine position |
| 1229 | memcpy(this->compensated_machine_position, transformed_target, n_motors*sizeof(float)); |
| 1230 | return true; |
| 1231 | } |
| 1232 | |
| 1233 | // no actual move |
| 1234 | return false; |
| 1235 | } |
| 1236 | |
| 1237 | // Used to plan a single move used by things like endstops when homing, zprobe, extruder firmware retracts etc. |
| 1238 | bool Robot::delta_move(const float *delta, float rate_mm_s, uint8_t naxis) |
| 1239 | { |
| 1240 | if(THEKERNEL->is_halted()) return false; |
| 1241 | |
| 1242 | // catch negative or zero feed rates |
| 1243 | if(rate_mm_s <= 0.0F) { |
| 1244 | return false; |
| 1245 | } |
| 1246 | |
| 1247 | // get the absolute target position, default is current machine_position |
| 1248 | float target[n_motors]; |
| 1249 | memcpy(target, machine_position, n_motors*sizeof(float)); |
| 1250 | |
| 1251 | // add in the deltas to get new target |
| 1252 | for (int i= 0; i < naxis; i++) { |
| 1253 | target[i] += delta[i]; |
| 1254 | } |
| 1255 | |
| 1256 | // submit for planning and if moved update machine_position |
| 1257 | if(append_milestone(target, rate_mm_s)) { |
| 1258 | memcpy(machine_position, target, n_motors*sizeof(float)); |
| 1259 | return true; |
| 1260 | } |
| 1261 | |
| 1262 | return false; |
| 1263 | } |
| 1264 | |
| 1265 | // Append a move to the queue ( cutting it into segments if needed ) |
| 1266 | bool Robot::append_line(Gcode *gcode, const float target[], float rate_mm_s, float delta_e) |
| 1267 | { |
| 1268 | // catch negative or zero feed rates and return the same error as GRBL does |
| 1269 | if(rate_mm_s <= 0.0F) { |
| 1270 | gcode->is_error= true; |
| 1271 | gcode->txt_after_ok= (rate_mm_s == 0 ? "Undefined feed rate" : "feed rate < 0"); |
| 1272 | return false; |
| 1273 | } |
| 1274 | |
| 1275 | // Find out the distance for this move in XYZ in MCS |
| 1276 | float millimeters_of_travel = sqrtf(powf( target[X_AXIS] - machine_position[X_AXIS], 2 ) + powf( target[Y_AXIS] - machine_position[Y_AXIS], 2 ) + powf( target[Z_AXIS] - machine_position[Z_AXIS], 2 )); |
| 1277 | |
| 1278 | if(millimeters_of_travel < 0.00001F) { |
| 1279 | // we have no movement in XYZ, probably E only extrude or retract |
| 1280 | return this->append_milestone(target, rate_mm_s); |
| 1281 | } |
| 1282 | |
| 1283 | /* |
| 1284 | For extruders, we need to do some extra work to limit the volumetric rate if specified... |
| 1285 | If using volumetric limts we need to be using volumetric extrusion for this to work as Ennn needs to be in mm³ not mm |
| 1286 | We ask Extruder to do all the work but we need to pass in the relevant data. |
| 1287 | NOTE we need to do this before we segment the line (for deltas) |
| 1288 | */ |
| 1289 | if(!isnan(delta_e) && gcode->has_g && gcode->g == 1) { |
| 1290 | float data[2]= {delta_e, rate_mm_s / millimeters_of_travel}; |
| 1291 | if(PublicData::set_value(extruder_checksum, target_checksum, data)) { |
| 1292 | rate_mm_s *= data[1]; // adjust the feedrate |
| 1293 | } |
| 1294 | } |
| 1295 | |
| 1296 | // We cut the line into smaller segments. This is only needed on a cartesian robot for zgrid, but always necessary for robots with rotational axes like Deltas. |
| 1297 | // In delta robots either mm_per_line_segment can be used OR delta_segments_per_second |
| 1298 | // 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 |
| 1299 | uint16_t segments; |
| 1300 | |
| 1301 | if(this->disable_segmentation || (!segment_z_moves && !gcode->has_letter('X') && !gcode->has_letter('Y'))) { |
| 1302 | segments= 1; |
| 1303 | |
| 1304 | } else if(this->delta_segments_per_second > 1.0F) { |
| 1305 | // enabled if set to something > 1, it is set to 0.0 by default |
| 1306 | // segment based on current speed and requested segments per second |
| 1307 | // the faster the travel speed the fewer segments needed |
| 1308 | // NOTE rate is mm/sec and we take into account any speed override |
| 1309 | float seconds = millimeters_of_travel / rate_mm_s; |
| 1310 | segments = max(1.0F, ceilf(this->delta_segments_per_second * seconds)); |
| 1311 | // TODO if we are only moving in Z on a delta we don't really need to segment at all |
| 1312 | |
| 1313 | } else { |
| 1314 | if(this->mm_per_line_segment == 0.0F) { |
| 1315 | segments = 1; // don't split it up |
| 1316 | } else { |
| 1317 | segments = ceilf( millimeters_of_travel / this->mm_per_line_segment); |
| 1318 | } |
| 1319 | } |
| 1320 | |
| 1321 | bool moved= false; |
| 1322 | if (segments > 1) { |
| 1323 | // A vector to keep track of the endpoint of each segment |
| 1324 | float segment_delta[n_motors]; |
| 1325 | float segment_end[n_motors]; |
| 1326 | memcpy(segment_end, machine_position, n_motors*sizeof(float)); |
| 1327 | |
| 1328 | // How far do we move each segment? |
| 1329 | for (int i = 0; i < n_motors; i++) |
| 1330 | segment_delta[i] = (target[i] - machine_position[i]) / segments; |
| 1331 | |
| 1332 | // segment 0 is already done - it's the end point of the previous move so we start at segment 1 |
| 1333 | // We always add another point after this loop so we stop at segments-1, ie i < segments |
| 1334 | for (int i = 1; i < segments; i++) { |
| 1335 | if(THEKERNEL->is_halted()) return false; // don't queue any more segments |
| 1336 | for (int i = 0; i < n_motors; i++) |
| 1337 | segment_end[i] += segment_delta[i]; |
| 1338 | |
| 1339 | // Append the end of this segment to the queue |
| 1340 | bool b= this->append_milestone(segment_end, rate_mm_s); |
| 1341 | moved= moved || b; |
| 1342 | } |
| 1343 | } |
| 1344 | |
| 1345 | // Append the end of this full move to the queue |
| 1346 | if(this->append_milestone(target, rate_mm_s)) moved= true; |
| 1347 | |
| 1348 | this->next_command_is_MCS = false; // always reset this |
| 1349 | |
| 1350 | return moved; |
| 1351 | } |
| 1352 | |
| 1353 | |
| 1354 | // Append an arc to the queue ( cutting it into segments as needed ) |
| 1355 | // TODO does not support any E parameters so cannot be used for 3D printing. |
| 1356 | bool Robot::append_arc(Gcode * gcode, const float target[], const float offset[], float radius, bool is_clockwise ) |
| 1357 | { |
| 1358 | float rate_mm_s= this->feed_rate / seconds_per_minute; |
| 1359 | // catch negative or zero feed rates and return the same error as GRBL does |
| 1360 | if(rate_mm_s <= 0.0F) { |
| 1361 | gcode->is_error= true; |
| 1362 | gcode->txt_after_ok= (rate_mm_s == 0 ? "Undefined feed rate" : "feed rate < 0"); |
| 1363 | return false; |
| 1364 | } |
| 1365 | |
| 1366 | // Scary math |
| 1367 | float center_axis0 = this->machine_position[this->plane_axis_0] + offset[this->plane_axis_0]; |
| 1368 | float center_axis1 = this->machine_position[this->plane_axis_1] + offset[this->plane_axis_1]; |
| 1369 | float linear_travel = target[this->plane_axis_2] - this->machine_position[this->plane_axis_2]; |
| 1370 | float r_axis0 = -offset[this->plane_axis_0]; // Radius vector from center to current location |
| 1371 | float r_axis1 = -offset[this->plane_axis_1]; |
| 1372 | float rt_axis0 = target[this->plane_axis_0] - center_axis0; |
| 1373 | float rt_axis1 = target[this->plane_axis_1] - center_axis1; |
| 1374 | |
| 1375 | // Patch from GRBL Firmware - Christoph Baumann 04072015 |
| 1376 | // CCW angle between position and target from circle center. Only one atan2() trig computation required. |
| 1377 | float angular_travel = atan2f(r_axis0 * rt_axis1 - r_axis1 * rt_axis0, r_axis0 * rt_axis0 + r_axis1 * rt_axis1); |
| 1378 | if (is_clockwise) { // Correct atan2 output per direction |
| 1379 | if (angular_travel >= -ARC_ANGULAR_TRAVEL_EPSILON) { angular_travel -= (2 * PI); } |
| 1380 | } else { |
| 1381 | if (angular_travel <= ARC_ANGULAR_TRAVEL_EPSILON) { angular_travel += (2 * PI); } |
| 1382 | } |
| 1383 | |
| 1384 | // Find the distance for this gcode |
| 1385 | float millimeters_of_travel = hypotf(angular_travel * radius, fabsf(linear_travel)); |
| 1386 | |
| 1387 | // We don't care about non-XYZ moves ( for example the extruder produces some of those ) |
| 1388 | if( millimeters_of_travel < 0.00001F ) { |
| 1389 | return false; |
| 1390 | } |
| 1391 | |
| 1392 | // limit segments by maximum arc error |
| 1393 | float arc_segment = this->mm_per_arc_segment; |
| 1394 | if ((this->mm_max_arc_error > 0) && (2 * radius > this->mm_max_arc_error)) { |
| 1395 | float min_err_segment = 2 * sqrtf((this->mm_max_arc_error * (2 * radius - this->mm_max_arc_error))); |
| 1396 | if (this->mm_per_arc_segment < min_err_segment) { |
| 1397 | arc_segment = min_err_segment; |
| 1398 | } |
| 1399 | } |
| 1400 | // Figure out how many segments for this gcode |
| 1401 | // TODO for deltas we need to make sure we are at least as many segments as requested, also if mm_per_line_segment is set we need to use the |
| 1402 | uint16_t segments = ceilf(millimeters_of_travel / arc_segment); |
| 1403 | |
| 1404 | //printf("Radius %f - Segment Length %f - Number of Segments %d\r\n",radius,arc_segment,segments); // Testing Purposes ONLY |
| 1405 | float theta_per_segment = angular_travel / segments; |
| 1406 | float linear_per_segment = linear_travel / segments; |
| 1407 | |
| 1408 | /* Vector rotation by transformation matrix: r is the original vector, r_T is the rotated vector, |
| 1409 | and phi is the angle of rotation. Based on the solution approach by Jens Geisler. |
| 1410 | r_T = [cos(phi) -sin(phi); |
| 1411 | sin(phi) cos(phi] * r ; |
| 1412 | For arc generation, the center of the circle is the axis of rotation and the radius vector is |
| 1413 | defined from the circle center to the initial position. Each line segment is formed by successive |
| 1414 | vector rotations. This requires only two cos() and sin() computations to form the rotation |
| 1415 | matrix for the duration of the entire arc. Error may accumulate from numerical round-off, since |
| 1416 | all float numbers are single precision on the Arduino. (True float precision will not have |
| 1417 | round off issues for CNC applications.) Single precision error can accumulate to be greater than |
| 1418 | tool precision in some cases. Therefore, arc path correction is implemented. |
| 1419 | |
| 1420 | Small angle approximation may be used to reduce computation overhead further. This approximation |
| 1421 | holds for everything, but very small circles and large mm_per_arc_segment values. In other words, |
| 1422 | theta_per_segment would need to be greater than 0.1 rad and N_ARC_CORRECTION would need to be large |
| 1423 | to cause an appreciable drift error. N_ARC_CORRECTION~=25 is more than small enough to correct for |
| 1424 | numerical drift error. N_ARC_CORRECTION may be on the order a hundred(s) before error becomes an |
| 1425 | issue for CNC machines with the single precision Arduino calculations. |
| 1426 | This approximation also allows mc_arc to immediately insert a line segment into the planner |
| 1427 | without the initial overhead of computing cos() or sin(). By the time the arc needs to be applied |
| 1428 | a correction, the planner should have caught up to the lag caused by the initial mc_arc overhead. |
| 1429 | This is important when there are successive arc motions. |
| 1430 | */ |
| 1431 | // Vector rotation matrix values |
| 1432 | float cos_T = 1 - 0.5F * theta_per_segment * theta_per_segment; // Small angle approximation |
| 1433 | float sin_T = theta_per_segment; |
| 1434 | |
| 1435 | // TODO we need to handle the ABC axis here by segmenting them |
| 1436 | float arc_target[3]; |
| 1437 | float sin_Ti; |
| 1438 | float cos_Ti; |
| 1439 | float r_axisi; |
| 1440 | uint16_t i; |
| 1441 | int8_t count = 0; |
| 1442 | |
| 1443 | // Initialize the linear axis |
| 1444 | arc_target[this->plane_axis_2] = this->machine_position[this->plane_axis_2]; |
| 1445 | |
| 1446 | bool moved= false; |
| 1447 | for (i = 1; i < segments; i++) { // Increment (segments-1) |
| 1448 | if(THEKERNEL->is_halted()) return false; // don't queue any more segments |
| 1449 | |
| 1450 | if (count < this->arc_correction ) { |
| 1451 | // Apply vector rotation matrix |
| 1452 | r_axisi = r_axis0 * sin_T + r_axis1 * cos_T; |
| 1453 | r_axis0 = r_axis0 * cos_T - r_axis1 * sin_T; |
| 1454 | r_axis1 = r_axisi; |
| 1455 | count++; |
| 1456 | } else { |
| 1457 | // Arc correction to radius vector. Computed only every N_ARC_CORRECTION increments. |
| 1458 | // Compute exact location by applying transformation matrix from initial radius vector(=-offset). |
| 1459 | cos_Ti = cosf(i * theta_per_segment); |
| 1460 | sin_Ti = sinf(i * theta_per_segment); |
| 1461 | r_axis0 = -offset[this->plane_axis_0] * cos_Ti + offset[this->plane_axis_1] * sin_Ti; |
| 1462 | r_axis1 = -offset[this->plane_axis_0] * sin_Ti - offset[this->plane_axis_1] * cos_Ti; |
| 1463 | count = 0; |
| 1464 | } |
| 1465 | |
| 1466 | // Update arc_target location |
| 1467 | arc_target[this->plane_axis_0] = center_axis0 + r_axis0; |
| 1468 | arc_target[this->plane_axis_1] = center_axis1 + r_axis1; |
| 1469 | arc_target[this->plane_axis_2] += linear_per_segment; |
| 1470 | |
| 1471 | // Append this segment to the queue |
| 1472 | bool b= this->append_milestone(arc_target, rate_mm_s); |
| 1473 | moved= moved || b; |
| 1474 | } |
| 1475 | |
| 1476 | // Ensure last segment arrives at target location. |
| 1477 | if(this->append_milestone(target, rate_mm_s)) moved= true; |
| 1478 | |
| 1479 | return moved; |
| 1480 | } |
| 1481 | |
| 1482 | // Do the math for an arc and add it to the queue |
| 1483 | bool Robot::compute_arc(Gcode * gcode, const float offset[], const float target[], enum MOTION_MODE_T motion_mode) |
| 1484 | { |
| 1485 | |
| 1486 | // Find the radius |
| 1487 | float radius = hypotf(offset[this->plane_axis_0], offset[this->plane_axis_1]); |
| 1488 | |
| 1489 | // Set clockwise/counter-clockwise sign for mc_arc computations |
| 1490 | bool is_clockwise = false; |
| 1491 | if( motion_mode == CW_ARC ) { |
| 1492 | is_clockwise = true; |
| 1493 | } |
| 1494 | |
| 1495 | // Append arc |
| 1496 | return this->append_arc(gcode, target, offset, radius, is_clockwise ); |
| 1497 | } |
| 1498 | |
| 1499 | |
| 1500 | float Robot::theta(float x, float y) |
| 1501 | { |
| 1502 | float t = atanf(x / fabs(y)); |
| 1503 | if (y > 0) { |
| 1504 | return(t); |
| 1505 | } else { |
| 1506 | if (t > 0) { |
| 1507 | return(PI - t); |
| 1508 | } else { |
| 1509 | return(-PI - t); |
| 1510 | } |
| 1511 | } |
| 1512 | } |
| 1513 | |
| 1514 | void Robot::select_plane(uint8_t axis_0, uint8_t axis_1, uint8_t axis_2) |
| 1515 | { |
| 1516 | this->plane_axis_0 = axis_0; |
| 1517 | this->plane_axis_1 = axis_1; |
| 1518 | this->plane_axis_2 = axis_2; |
| 1519 | } |
| 1520 | |
| 1521 | void Robot::clearToolOffset() |
| 1522 | { |
| 1523 | this->tool_offset= wcs_t(0,0,0); |
| 1524 | } |
| 1525 | |
| 1526 | void Robot::setToolOffset(const float offset[3]) |
| 1527 | { |
| 1528 | this->tool_offset= wcs_t(offset[0], offset[1], offset[2]); |
| 1529 | } |
| 1530 | |
| 1531 | float Robot::get_feed_rate() const |
| 1532 | { |
| 1533 | return THEKERNEL->gcode_dispatch->get_modal_command() == 0 ? seek_rate : feed_rate; |
| 1534 | } |