Pin status from 0 - 255
*/
inline void gcode_M42() {
if (code_seen('S')) {
int pin_status = code_value_short();
if (pin_status < 0 || pin_status > 255) return;
int pin_number = code_seen('P') ? code_value_short() : LED_PIN;
if (pin_number < 0) return;
for (uint8_t i = 0; i < COUNT(sensitive_pins); i++)
if (pin_number == sensitive_pins[i]) return;
pinMode(pin_number, OUTPUT);
digitalWrite(pin_number, pin_status);
analogWrite(pin_number, pin_status);
#if FAN_COUNT > 0
switch (pin_number) {
#if HAS_FAN0
case FAN_PIN: fanSpeeds[0] = pin_status; break;
#endif
#if HAS_FAN1
case FAN1_PIN: fanSpeeds[1] = pin_status; break;
#endif
#if HAS_FAN2
case FAN2_PIN: fanSpeeds[2] = pin_status; break;
#endif
}
#endif
} // code_seen('S')
}
#if ENABLED(AUTO_BED_LEVELING_FEATURE) && ENABLED(Z_MIN_PROBE_REPEATABILITY_TEST)
/**
* This is redundant since the SanityCheck.h already checks for a valid
* Z_MIN_PROBE_PIN, but here for clarity.
*/
#if ENABLED(Z_MIN_PROBE_ENDSTOP)
#if !HAS_Z_PROBE
#error You must define Z_MIN_PROBE_PIN to enable Z probe repeatability calculation.
#endif
#elif !HAS_Z_MIN
#error You must define Z_MIN_PIN to enable Z probe repeatability calculation.
#endif
/**
* M48: Z probe repeatability measurement function.
*
* Usage:
* M48
* P = Number of sampled points (4-50, default 10)
* X = Sample X position
* Y = Sample Y position
* V = Verbose level (0-4, default=1)
* E = Engage Z probe for each reading
* L = Number of legs of movement before probe
* S = Schizoid (Or Star if you prefer)
*
* This function assumes the bed has been homed. Specifically, that a G28 command
* as been issued prior to invoking the M48 Z probe repeatability measurement function.
* Any information generated by a prior G29 Bed leveling command will be lost and need to be
* regenerated.
*/
inline void gcode_M48() {
if (!axis_homed[X_AXIS] || !axis_homed[Y_AXIS] || !axis_homed[Z_AXIS]) {
axis_unhomed_error();
return;
}
double sum = 0.0, mean = 0.0, sigma = 0.0, sample_set[50];
int8_t verbose_level = 1, n_samples = 10, n_legs = 0, schizoid_flag = 0;
if (code_seen('V')) {
verbose_level = code_value_short();
if (verbose_level < 0 || verbose_level > 4) {
SERIAL_PROTOCOLPGM("?Verbose Level not plausible (0-4).\n");
return;
}
}
if (verbose_level > 0)
SERIAL_PROTOCOLPGM("M48 Z-Probe Repeatability test\n");
if (code_seen('P')) {
n_samples = code_value_short();
if (n_samples < 4 || n_samples > 50) {
SERIAL_PROTOCOLPGM("?Sample size not plausible (4-50).\n");
return;
}
}
float X_current = current_position[X_AXIS],
Y_current = current_position[Y_AXIS],
Z_current = current_position[Z_AXIS],
X_probe_location = X_current + X_PROBE_OFFSET_FROM_EXTRUDER,
Y_probe_location = Y_current + Y_PROBE_OFFSET_FROM_EXTRUDER,
Z_start_location = Z_current + Z_RAISE_BEFORE_PROBING;
bool deploy_probe_for_each_reading = code_seen('E');
if (code_seen('X')) {
X_probe_location = code_value();
#if DISABLED(DELTA)
if (X_probe_location < MIN_PROBE_X || X_probe_location > MAX_PROBE_X) {
out_of_range_error(PSTR("X"));
return;
}
#endif
}
if (code_seen('Y')) {
Y_probe_location = code_value();
#if DISABLED(DELTA)
if (Y_probe_location < MIN_PROBE_Y || Y_probe_location > MAX_PROBE_Y) {
out_of_range_error(PSTR("Y"));
return;
}
#endif
}
#if ENABLED(DELTA)
if (sqrt(X_probe_location * X_probe_location + Y_probe_location * Y_probe_location) > DELTA_PROBEABLE_RADIUS) {
SERIAL_PROTOCOLPGM("? (X,Y) location outside of probeable radius.\n");
return;
}
#endif
bool seen_L = code_seen('L');
if (seen_L) {
n_legs = code_value_short();
if (n_legs < 0 || n_legs > 15) {
SERIAL_PROTOCOLPGM("?Number of legs in movement not plausible (0-15).\n");
return;
}
if (n_legs == 1) n_legs = 2;
}
if (code_seen('S')) {
schizoid_flag++;
if (!seen_L) n_legs = 7;
}
/**
* Now get everything to the specified probe point So we can safely do a
* probe to get us close to the bed. If the Z-Axis is far from the bed,
* we don't want to use that as a starting point for each probe.
*/
if (verbose_level > 2)
SERIAL_PROTOCOLPGM("Positioning the probe...\n");
#if ENABLED(DELTA)
// we don't do bed level correction in M48 because we want the raw data when we probe
reset_bed_level();
#else
// we don't do bed level correction in M48 because we want the raw data when we probe
plan_bed_level_matrix.set_to_identity();
#endif
if (Z_start_location < Z_RAISE_BEFORE_PROBING * 2.0)
do_blocking_move_to_z(Z_start_location);
do_blocking_move_to_xy(X_probe_location - X_PROBE_OFFSET_FROM_EXTRUDER, Y_probe_location - Y_PROBE_OFFSET_FROM_EXTRUDER);
/**
* OK, do the initial probe to get us close to the bed.
* Then retrace the right amount and use that in subsequent probes
*/
setup_for_endstop_move();
probe_pt(X_probe_location, Y_probe_location, Z_RAISE_BEFORE_PROBING,
deploy_probe_for_each_reading ? ProbeDeployAndStow : ProbeDeploy,
verbose_level);
raise_z_after_probing();
for (uint8_t n = 0; n < n_samples; n++) {
randomSeed(millis());
delay(500);
if (n_legs) {
float radius, angle = random(0.0, 360.0);
int dir = (random(0, 10) > 5.0) ? -1 : 1; // clockwise or counter clockwise
radius = random(
#if ENABLED(DELTA)
DELTA_PROBEABLE_RADIUS / 8, DELTA_PROBEABLE_RADIUS / 3
#else
5, X_MAX_LENGTH / 8
#endif
);
if (verbose_level > 3) {
SERIAL_ECHOPAIR("Starting radius: ", radius);
SERIAL_ECHOPAIR(" angle: ", angle);
delay(100);
if (dir > 0)
SERIAL_ECHO(" Direction: Counter Clockwise \n");
else
SERIAL_ECHO(" Direction: Clockwise \n");
delay(100);
}
for (uint8_t l = 0; l < n_legs - 1; l++) {
double delta_angle;
if (schizoid_flag)
// The points of a 5 point star are 72 degrees apart. We need to
// skip a point and go to the next one on the star.
delta_angle = dir * 2.0 * 72.0;
else
// If we do this line, we are just trying to move further
// around the circle.
delta_angle = dir * (float) random(25, 45);
angle += delta_angle;
while (angle > 360.0) // We probably do not need to keep the angle between 0 and 2*PI, but the
angle -= 360.0; // Arduino documentation says the trig functions should not be given values
while (angle < 0.0) // outside of this range. It looks like they behave correctly with
angle += 360.0; // numbers outside of the range, but just to be safe we clamp them.
X_current = X_probe_location - X_PROBE_OFFSET_FROM_EXTRUDER + cos(RADIANS(angle)) * radius;
Y_current = Y_probe_location - Y_PROBE_OFFSET_FROM_EXTRUDER + sin(RADIANS(angle)) * radius;
#if DISABLED(DELTA)
X_current = constrain(X_current, X_MIN_POS, X_MAX_POS);
Y_current = constrain(Y_current, Y_MIN_POS, Y_MAX_POS);
#else
// If we have gone out too far, we can do a simple fix and scale the numbers
// back in closer to the origin.
while (sqrt(X_current * X_current + Y_current * Y_current) > DELTA_PROBEABLE_RADIUS) {
X_current /= 1.25;
Y_current /= 1.25;
if (verbose_level > 3) {
SERIAL_ECHOPAIR("Pulling point towards center:", X_current);
SERIAL_ECHOPAIR(", ", Y_current);
SERIAL_EOL;
delay(50);
}
}
#endif
if (verbose_level > 3) {
SERIAL_PROTOCOL("Going to:");
SERIAL_ECHOPAIR("x: ", X_current);
SERIAL_ECHOPAIR("y: ", Y_current);
SERIAL_ECHOPAIR(" z: ", current_position[Z_AXIS]);
SERIAL_EOL;
delay(55);
}
do_blocking_move_to_xy(X_current, Y_current);
} // n_legs loop
} // n_legs
/**
* We don't really have to do this move, but if we don't we can see a
* funny shift in the Z Height because the user might not have the
* Z_RAISE_BEFORE_PROBING height identical to the Z_RAISE_BETWEEN_PROBING
* height. This gets us back to the probe location at the same height that
* we have been running around the circle at.
*/
do_blocking_move_to_xy(X_probe_location - X_PROBE_OFFSET_FROM_EXTRUDER, Y_probe_location - Y_PROBE_OFFSET_FROM_EXTRUDER);
if (deploy_probe_for_each_reading)
sample_set[n] = probe_pt(X_probe_location, Y_probe_location, Z_RAISE_BEFORE_PROBING, ProbeDeployAndStow, verbose_level);
else {
if (n == n_samples - 1)
sample_set[n] = probe_pt(X_probe_location, Y_probe_location, Z_RAISE_BEFORE_PROBING, ProbeStow, verbose_level); else
sample_set[n] = probe_pt(X_probe_location, Y_probe_location, Z_RAISE_BEFORE_PROBING, ProbeStay, verbose_level);
}
/**
* Get the current mean for the data points we have so far
*/
sum = 0.0;
for (uint8_t j = 0; j <= n; j++) sum += sample_set[j];
mean = sum / (n + 1);
/**
* Now, use that mean to calculate the standard deviation for the
* data points we have so far
*/
sum = 0.0;
for (uint8_t j = 0; j <= n; j++) {
float ss = sample_set[j] - mean;
sum += ss * ss;
}
sigma = sqrt(sum / (n + 1));
if (verbose_level > 1) {
SERIAL_PROTOCOL(n + 1);
SERIAL_PROTOCOLPGM(" of ");
SERIAL_PROTOCOL((int)n_samples);
SERIAL_PROTOCOLPGM(" z: ");
SERIAL_PROTOCOL_F(current_position[Z_AXIS], 6);
delay(50);
if (verbose_level > 2) {
SERIAL_PROTOCOLPGM(" mean: ");
SERIAL_PROTOCOL_F(mean, 6);
SERIAL_PROTOCOLPGM(" sigma: ");
SERIAL_PROTOCOL_F(sigma, 6);
}
}
if (verbose_level > 0) SERIAL_EOL;
delay(50);
do_blocking_move_to_z(current_position[Z_AXIS] + Z_RAISE_BETWEEN_PROBINGS);
} // End of probe loop code
// raise_z_after_probing();
if (verbose_level > 0) {
SERIAL_PROTOCOLPGM("Mean: ");
SERIAL_PROTOCOL_F(mean, 6);
SERIAL_EOL;
delay(25);
}
SERIAL_PROTOCOLPGM("Standard Deviation: ");
SERIAL_PROTOCOL_F(sigma, 6);
SERIAL_EOL; SERIAL_EOL;
delay(25);
clean_up_after_endstop_move();
gcode_M114(); // Send end position to RepetierHost
}
#endif // AUTO_BED_LEVELING_FEATURE && Z_MIN_PROBE_REPEATABILITY_TEST
/**
* M104: Set hot end temperature
*/
inline void gcode_M104() {
if (setTargetedHotend(104)) return;
if (DEBUGGING(DRYRUN)) return;
// Start hook must happen before setTargetHotend()
print_job_start();
if (code_seen('S')) {
float temp = code_value();
setTargetHotend(temp, target_extruder);
#if ENABLED(DUAL_X_CARRIAGE)
if (dual_x_carriage_mode == DXC_DUPLICATION_MODE && target_extruder == 0)
setTargetHotend1(temp == 0.0 ? 0.0 : temp + duplicate_extruder_temp_offset);
#endif
if (temp > degHotend(target_extruder)) LCD_MESSAGEPGM(MSG_HEATING);
}
if (print_job_stop()) LCD_MESSAGEPGM(WELCOME_MSG);
}
#if HAS_TEMP_0 || HAS_TEMP_BED || ENABLED(HEATER_0_USES_MAX6675)
void print_heaterstates() {
#if HAS_TEMP_0 || ENABLED(HEATER_0_USES_MAX6675)
SERIAL_PROTOCOLPGM(" T:");
SERIAL_PROTOCOL_F(degHotend(target_extruder), 1);
SERIAL_PROTOCOLPGM(" /");
SERIAL_PROTOCOL_F(degTargetHotend(target_extruder), 1);
#endif
#if HAS_TEMP_BED
SERIAL_PROTOCOLPGM(" B:");
SERIAL_PROTOCOL_F(degBed(), 1);
SERIAL_PROTOCOLPGM(" /");
SERIAL_PROTOCOL_F(degTargetBed(), 1);
#endif
#if EXTRUDERS > 1
for (int8_t e = 0; e < EXTRUDERS; ++e) {
SERIAL_PROTOCOLPGM(" T");
SERIAL_PROTOCOL(e);
SERIAL_PROTOCOLCHAR(':');
SERIAL_PROTOCOL_F(degHotend(e), 1);
SERIAL_PROTOCOLPGM(" /");
SERIAL_PROTOCOL_F(degTargetHotend(e), 1);
}
#endif
#if HAS_TEMP_BED
SERIAL_PROTOCOLPGM(" B@:");
#ifdef BED_WATTS
SERIAL_PROTOCOL(((BED_WATTS) * getHeaterPower(-1)) / 127);
SERIAL_PROTOCOLCHAR('W');
#else
SERIAL_PROTOCOL(getHeaterPower(-1));
#endif
#endif
SERIAL_PROTOCOLPGM(" @:");
#ifdef EXTRUDER_WATTS
SERIAL_PROTOCOL(((EXTRUDER_WATTS) * getHeaterPower(target_extruder)) / 127);
SERIAL_PROTOCOLCHAR('W');
#else
SERIAL_PROTOCOL(getHeaterPower(target_extruder));
#endif
#if EXTRUDERS > 1
for (int8_t e = 0; e < EXTRUDERS; ++e) {
SERIAL_PROTOCOLPGM(" @");
SERIAL_PROTOCOL(e);
SERIAL_PROTOCOLCHAR(':');
#ifdef EXTRUDER_WATTS
SERIAL_PROTOCOL(((EXTRUDER_WATTS) * getHeaterPower(e)) / 127);
SERIAL_PROTOCOLCHAR('W');
#else
SERIAL_PROTOCOL(getHeaterPower(e));
#endif
}
#endif
#if ENABLED(SHOW_TEMP_ADC_VALUES)
#if HAS_TEMP_BED
SERIAL_PROTOCOLPGM(" ADC B:");
SERIAL_PROTOCOL_F(degBed(), 1);
SERIAL_PROTOCOLPGM("C->");
SERIAL_PROTOCOL_F(rawBedTemp() / OVERSAMPLENR, 0);
#endif
for (int8_t cur_extruder = 0; cur_extruder < EXTRUDERS; ++cur_extruder) {
SERIAL_PROTOCOLPGM(" T");
SERIAL_PROTOCOL(cur_extruder);
SERIAL_PROTOCOLCHAR(':');
SERIAL_PROTOCOL_F(degHotend(cur_extruder), 1);
SERIAL_PROTOCOLPGM("C->");
SERIAL_PROTOCOL_F(rawHotendTemp(cur_extruder) / OVERSAMPLENR, 0);
}
#endif
}
#endif
/**
* M105: Read hot end and bed temperature
*/
inline void gcode_M105() {
if (setTargetedHotend(105)) return;
#if HAS_TEMP_0 || HAS_TEMP_BED || ENABLED(HEATER_0_USES_MAX6675)
SERIAL_PROTOCOLPGM(MSG_OK);
print_heaterstates();
#else // !HAS_TEMP_0 && !HAS_TEMP_BED
SERIAL_ERROR_START;
SERIAL_ERRORLNPGM(MSG_ERR_NO_THERMISTORS);
#endif
SERIAL_EOL;
}
#if FAN_COUNT > 0
/**
* M106: Set Fan Speed
*
* S Speed between 0-255
* P Fan index, if more than one fan
*/
inline void gcode_M106() {
uint16_t s = code_seen('S') ? code_value_short() : 255,
p = code_seen('P') ? code_value_short() : 0;
NOMORE(s, 255);
if (p < FAN_COUNT) fanSpeeds[p] = s;
}
/**
* M107: Fan Off
*/
inline void gcode_M107() {
uint16_t p = code_seen('P') ? code_value_short() : 0;
if (p < FAN_COUNT) fanSpeeds[p] = 0;
}
#endif // FAN_COUNT > 0
/**
* M109: Sxxx Wait for extruder(s) to reach temperature. Waits only when heating.
* Rxxx Wait for extruder(s) to reach temperature. Waits when heating and cooling.
*/
inline void gcode_M109() {
bool no_wait_for_cooling = true;
if (setTargetedHotend(109)) return;
if (DEBUGGING(DRYRUN)) return;
// Start hook must happen before setTargetHotend()
print_job_start();
no_wait_for_cooling = code_seen('S');
if (no_wait_for_cooling || code_seen('R')) {
float temp = code_value();
setTargetHotend(temp, target_extruder);
#if ENABLED(DUAL_X_CARRIAGE)
if (dual_x_carriage_mode == DXC_DUPLICATION_MODE && target_extruder == 0)
setTargetHotend1(temp == 0.0 ? 0.0 : temp + duplicate_extruder_temp_offset);
#endif
if (temp > degHotend(target_extruder)) LCD_MESSAGEPGM(MSG_HEATING);
}
if (print_job_stop()) LCD_MESSAGEPGM(WELCOME_MSG);
#if ENABLED(AUTOTEMP)
autotemp_enabled = code_seen('F');
if (autotemp_enabled) autotemp_factor = code_value();
if (code_seen('S')) autotemp_min = code_value();
if (code_seen('B')) autotemp_max = code_value();
#endif
// Exit if the temperature is above target and not waiting for cooling
if (no_wait_for_cooling && !isHeatingHotend(target_extruder)) return;
// Prevents a wait-forever situation if R is misused i.e. M109 R0
// Try to calculate a ballpark safe margin by halving EXTRUDE_MINTEMP
if (degTargetHotend(target_extruder) < (EXTRUDE_MINTEMP/2)) return;
#ifdef TEMP_RESIDENCY_TIME
long residency_start_ms = -1;
// Loop until the temperature has stabilized
#define TEMP_CONDITIONS (residency_start_ms < 0 || now < residency_start_ms + (TEMP_RESIDENCY_TIME) * 1000UL)
#else
// Loop until the temperature is very close target
#define TEMP_CONDITIONS (isHeatingHotend(target_extruder))
#endif //TEMP_RESIDENCY_TIME
cancel_heatup = false;
millis_t now = millis(), next_temp_ms = now + 1000UL;
while (!cancel_heatup && TEMP_CONDITIONS) {
now = millis();
if (now > next_temp_ms) { //Print temp & remaining time every 1s while waiting
next_temp_ms = now + 1000UL;
#if HAS_TEMP_0 || HAS_TEMP_BED || ENABLED(HEATER_0_USES_MAX6675)
print_heaterstates();
#endif
#ifdef TEMP_RESIDENCY_TIME
SERIAL_PROTOCOLPGM(" W:");
if (residency_start_ms >= 0) {
long rem = (((TEMP_RESIDENCY_TIME) * 1000UL) - (now - residency_start_ms)) / 1000UL;
SERIAL_PROTOCOLLN(rem);
}
else {
SERIAL_PROTOCOLLNPGM("?");
}
#else
SERIAL_EOL;
#endif
}
idle();
refresh_cmd_timeout(); // to prevent stepper_inactive_time from running out
#ifdef TEMP_RESIDENCY_TIME
// Start the TEMP_RESIDENCY_TIME timer when we reach target temp for the first time.
// Restart the timer whenever the temperature falls outside the hysteresis.
if (labs(degHotend(target_extruder) - degTargetHotend(target_extruder)) > ((residency_start_ms < 0) ? TEMP_WINDOW : TEMP_HYSTERESIS))
residency_start_ms = millis();
#endif //TEMP_RESIDENCY_TIME
} // while(!cancel_heatup && TEMP_CONDITIONS)
LCD_MESSAGEPGM(MSG_HEATING_COMPLETE);
}
#if HAS_TEMP_BED
/**
* M190: Sxxx Wait for bed current temp to reach target temp. Waits only when heating
* Rxxx Wait for bed current temp to reach target temp. Waits when heating and cooling
*/
inline void gcode_M190() {
if (DEBUGGING(DRYRUN)) return;
LCD_MESSAGEPGM(MSG_BED_HEATING);
bool no_wait_for_cooling = code_seen('S');
if (no_wait_for_cooling || code_seen('R'))
setTargetBed(code_value());
// Exit if the temperature is above target and not waiting for cooling
if (no_wait_for_cooling && !isHeatingBed()) return;
cancel_heatup = false;
millis_t now = millis(), next_temp_ms = now + 1000UL;
while (!cancel_heatup && isHeatingBed()) {
millis_t now = millis();
if (now > next_temp_ms) { //Print Temp Reading every 1 second while heating up.
next_temp_ms = now + 1000UL;
print_heaterstates();
SERIAL_EOL;
}
idle();
refresh_cmd_timeout(); // to prevent stepper_inactive_time from running out
}
LCD_MESSAGEPGM(MSG_BED_DONE);
}
#endif // HAS_TEMP_BED
/**
* M110: Set Current Line Number
*/
inline void gcode_M110() {
if (code_seen('N')) gcode_N = code_value_long();
}
/**
* M111: Set the debug level
*/
inline void gcode_M111() {
marlin_debug_flags = code_seen('S') ? code_value_short() : DEBUG_NONE;
const char str_debug_1[] PROGMEM = MSG_DEBUG_ECHO;
const char str_debug_2[] PROGMEM = MSG_DEBUG_INFO;
const char str_debug_4[] PROGMEM = MSG_DEBUG_ERRORS;
const char str_debug_8[] PROGMEM = MSG_DEBUG_DRYRUN;
const char str_debug_16[] PROGMEM = MSG_DEBUG_COMMUNICATION;
#if ENABLED(DEBUG_LEVELING_FEATURE)
const char str_debug_32[] PROGMEM = MSG_DEBUG_LEVELING;
#endif
const char* const debug_strings[] PROGMEM = {
str_debug_1, str_debug_2, str_debug_4, str_debug_8, str_debug_16,
#if ENABLED(DEBUG_LEVELING_FEATURE)
str_debug_32
#endif
};
SERIAL_ECHO_START;
SERIAL_ECHOPGM(MSG_DEBUG_PREFIX);
if (marlin_debug_flags) {
uint8_t comma = 0;
for (uint8_t i = 0; i < COUNT(debug_strings); i++) {
if (TEST(marlin_debug_flags, i)) {
if (comma++) SERIAL_CHAR('|');
serialprintPGM(debug_strings[i]);
}
}
}
else {
SERIAL_ECHOPGM(MSG_DEBUG_OFF);
}
SERIAL_EOL;
}
/**
* M112: Emergency Stop
*/
inline void gcode_M112() { kill(PSTR(MSG_KILLED)); }
#if ENABLED(BARICUDA)
#if HAS_HEATER_1
/**
* M126: Heater 1 valve open
*/
inline void gcode_M126() { ValvePressure = code_seen('S') ? constrain(code_value(), 0, 255) : 255; }
/**
* M127: Heater 1 valve close
*/
inline void gcode_M127() { ValvePressure = 0; }
#endif
#if HAS_HEATER_2
/**
* M128: Heater 2 valve open
*/
inline void gcode_M128() { EtoPPressure = code_seen('S') ? constrain(code_value(), 0, 255) : 255; }
/**
* M129: Heater 2 valve close
*/
inline void gcode_M129() { EtoPPressure = 0; }
#endif
#endif //BARICUDA
/**
* M140: Set bed temperature
*/
inline void gcode_M140() {
if (DEBUGGING(DRYRUN)) return;
if (code_seen('S')) setTargetBed(code_value());
}
#if ENABLED(ULTIPANEL)
/**
* M145: Set the heatup state for a material in the LCD menu
* S (0=PLA, 1=ABS)
* H
* B
* F
*/
inline void gcode_M145() {
int8_t material = code_seen('S') ? code_value_short() : 0;
if (material < 0 || material > 1) {
SERIAL_ERROR_START;
SERIAL_ERRORLNPGM(MSG_ERR_MATERIAL_INDEX);
}
else {
int v;
switch (material) {
case 0:
if (code_seen('H')) {
v = code_value_short();
plaPreheatHotendTemp = constrain(v, EXTRUDE_MINTEMP, HEATER_0_MAXTEMP - 15);
}
if (code_seen('F')) {
v = code_value_short();
plaPreheatFanSpeed = constrain(v, 0, 255);
}
#if TEMP_SENSOR_BED != 0
if (code_seen('B')) {
v = code_value_short();
plaPreheatHPBTemp = constrain(v, BED_MINTEMP, BED_MAXTEMP - 15);
}
#endif
break;
case 1:
if (code_seen('H')) {
v = code_value_short();
absPreheatHotendTemp = constrain(v, EXTRUDE_MINTEMP, HEATER_0_MAXTEMP - 15);
}
if (code_seen('F')) {
v = code_value_short();
absPreheatFanSpeed = constrain(v, 0, 255);
}
#if TEMP_SENSOR_BED != 0
if (code_seen('B')) {
v = code_value_short();
absPreheatHPBTemp = constrain(v, BED_MINTEMP, BED_MAXTEMP - 15);
}
#endif
break;
}
}
}
#endif
#if HAS_POWER_SWITCH
/**
* M80: Turn on Power Supply
*/
inline void gcode_M80() {
OUT_WRITE(PS_ON_PIN, PS_ON_AWAKE); //GND
/**
* If you have a switch on suicide pin, this is useful
* if you want to start another print with suicide feature after
* a print without suicide...
*/
#if HAS_SUICIDE
OUT_WRITE(SUICIDE_PIN, HIGH);
#endif
#if ENABLED(ULTIPANEL)
powersupply = true;
LCD_MESSAGEPGM(WELCOME_MSG);
lcd_update();
#endif
}
#endif // HAS_POWER_SWITCH
/**
* M81: Turn off Power, including Power Supply, if there is one.
*
* This code should ALWAYS be available for EMERGENCY SHUTDOWN!
*/
inline void gcode_M81() {
disable_all_heaters();
finishAndDisableSteppers();
#if FAN_COUNT > 0
#if FAN_COUNT > 1
for (uint8_t i = 0; i < FAN_COUNT; i++) fanSpeeds[i] = 0;
#else
fanSpeeds[0] = 0;
#endif
#endif
delay(1000); // Wait 1 second before switching off
#if HAS_SUICIDE
st_synchronize();
suicide();
#elif HAS_POWER_SWITCH
OUT_WRITE(PS_ON_PIN, PS_ON_ASLEEP);
#endif
#if ENABLED(ULTIPANEL)
#if HAS_POWER_SWITCH
powersupply = false;
#endif
LCD_MESSAGEPGM(MACHINE_NAME " " MSG_OFF ".");
lcd_update();
#endif
}
/**
* M82: Set E codes absolute (default)
*/
inline void gcode_M82() { axis_relative_modes[E_AXIS] = false; }
/**
* M83: Set E codes relative while in Absolute Coordinates (G90) mode
*/
inline void gcode_M83() { axis_relative_modes[E_AXIS] = true; }
/**
* M18, M84: Disable all stepper motors
*/
inline void gcode_M18_M84() {
if (code_seen('S')) {
stepper_inactive_time = code_value() * 1000;
}
else {
bool all_axis = !((code_seen(axis_codes[X_AXIS])) || (code_seen(axis_codes[Y_AXIS])) || (code_seen(axis_codes[Z_AXIS])) || (code_seen(axis_codes[E_AXIS])));
if (all_axis) {
finishAndDisableSteppers();
}
else {
st_synchronize();
if (code_seen('X')) disable_x();
if (code_seen('Y')) disable_y();
if (code_seen('Z')) disable_z();
#if ((E0_ENABLE_PIN != X_ENABLE_PIN) && (E1_ENABLE_PIN != Y_ENABLE_PIN)) // Only enable on boards that have seperate ENABLE_PINS
if (code_seen('E')) {
disable_e0();
disable_e1();
disable_e2();
disable_e3();
}
#endif
}
}
}
/**
* M85: Set inactivity shutdown timer with parameter S. To disable set zero (default)
*/
inline void gcode_M85() {
if (code_seen('S')) max_inactive_time = code_value() * 1000;
}
/**
* M92: Set axis steps-per-unit for one or more axes, X, Y, Z, and E.
* (Follows the same syntax as G92)
*/
inline void gcode_M92() {
for (int8_t i = 0; i < NUM_AXIS; i++) {
if (code_seen(axis_codes[i])) {
if (i == E_AXIS) {
float value = code_value();
if (value < 20.0) {
float factor = axis_steps_per_unit[i] / value; // increase e constants if M92 E14 is given for netfab.
max_e_jerk *= factor;
max_feedrate[i] *= factor;
axis_steps_per_sqr_second[i] *= factor;
}
axis_steps_per_unit[i] = value;
}
else {
axis_steps_per_unit[i] = code_value();
}
}
}
}
/**
* M114: Output current position to serial port
*/
inline void gcode_M114() {
SERIAL_PROTOCOLPGM("X:");
SERIAL_PROTOCOL(current_position[X_AXIS]);
SERIAL_PROTOCOLPGM(" Y:");
SERIAL_PROTOCOL(current_position[Y_AXIS]);
SERIAL_PROTOCOLPGM(" Z:");
SERIAL_PROTOCOL(current_position[Z_AXIS]);
SERIAL_PROTOCOLPGM(" E:");
SERIAL_PROTOCOL(current_position[E_AXIS]);
CRITICAL_SECTION_START;
extern volatile long count_position[NUM_AXIS];
long xpos = count_position[X_AXIS],
ypos = count_position[Y_AXIS],
zpos = count_position[Z_AXIS];
CRITICAL_SECTION_END;
#if ENABLED(COREXY) || ENABLED(COREXZ)
SERIAL_PROTOCOLPGM(MSG_COUNT_A);
#else
SERIAL_PROTOCOLPGM(MSG_COUNT_X);
#endif
SERIAL_PROTOCOL(xpos);
#if ENABLED(COREXY)
SERIAL_PROTOCOLPGM(" B:");
#else
SERIAL_PROTOCOLPGM(" Y:");
#endif
SERIAL_PROTOCOL(ypos);
#if ENABLED(COREXZ)
SERIAL_PROTOCOLPGM(" C:");
#else
SERIAL_PROTOCOLPGM(" Z:");
#endif
SERIAL_PROTOCOL(zpos);
SERIAL_EOL;
#if ENABLED(SCARA)
SERIAL_PROTOCOLPGM("SCARA Theta:");
SERIAL_PROTOCOL(delta[X_AXIS]);
SERIAL_PROTOCOLPGM(" Psi+Theta:");
SERIAL_PROTOCOL(delta[Y_AXIS]);
SERIAL_EOL;
SERIAL_PROTOCOLPGM("SCARA Cal - Theta:");
SERIAL_PROTOCOL(delta[X_AXIS] + home_offset[X_AXIS]);
SERIAL_PROTOCOLPGM(" Psi+Theta (90):");
SERIAL_PROTOCOL(delta[Y_AXIS] - delta[X_AXIS] - 90 + home_offset[Y_AXIS]);
SERIAL_EOL;
SERIAL_PROTOCOLPGM("SCARA step Cal - Theta:");
SERIAL_PROTOCOL(delta[X_AXIS] / 90 * axis_steps_per_unit[X_AXIS]);
SERIAL_PROTOCOLPGM(" Psi+Theta:");
SERIAL_PROTOCOL((delta[Y_AXIS] - delta[X_AXIS]) / 90 * axis_steps_per_unit[Y_AXIS]);
SERIAL_EOL; SERIAL_EOL;
#endif
}
/**
* M115: Capabilities string
*/
inline void gcode_M115() {
SERIAL_PROTOCOLPGM(MSG_M115_REPORT);
}
/**
* M117: Set LCD Status Message
*/
inline void gcode_M117() {
lcd_setstatus(current_command_args);
}
/**
* M119: Output endstop states to serial output
*/
inline void gcode_M119() {
SERIAL_PROTOCOLLN(MSG_M119_REPORT);
#if HAS_X_MIN
SERIAL_PROTOCOLPGM(MSG_X_MIN);
SERIAL_PROTOCOLLN(((READ(X_MIN_PIN)^X_MIN_ENDSTOP_INVERTING) ? MSG_ENDSTOP_HIT : MSG_ENDSTOP_OPEN));
#endif
#if HAS_X_MAX
SERIAL_PROTOCOLPGM(MSG_X_MAX);
SERIAL_PROTOCOLLN(((READ(X_MAX_PIN)^X_MAX_ENDSTOP_INVERTING) ? MSG_ENDSTOP_HIT : MSG_ENDSTOP_OPEN));
#endif
#if HAS_Y_MIN
SERIAL_PROTOCOLPGM(MSG_Y_MIN);
SERIAL_PROTOCOLLN(((READ(Y_MIN_PIN)^Y_MIN_ENDSTOP_INVERTING) ? MSG_ENDSTOP_HIT : MSG_ENDSTOP_OPEN));
#endif
#if HAS_Y_MAX
SERIAL_PROTOCOLPGM(MSG_Y_MAX);
SERIAL_PROTOCOLLN(((READ(Y_MAX_PIN)^Y_MAX_ENDSTOP_INVERTING) ? MSG_ENDSTOP_HIT : MSG_ENDSTOP_OPEN));
#endif
#if HAS_Z_MIN
SERIAL_PROTOCOLPGM(MSG_Z_MIN);
SERIAL_PROTOCOLLN(((READ(Z_MIN_PIN)^Z_MIN_ENDSTOP_INVERTING) ? MSG_ENDSTOP_HIT : MSG_ENDSTOP_OPEN));
#endif
#if HAS_Z_MAX
SERIAL_PROTOCOLPGM(MSG_Z_MAX);
SERIAL_PROTOCOLLN(((READ(Z_MAX_PIN)^Z_MAX_ENDSTOP_INVERTING) ? MSG_ENDSTOP_HIT : MSG_ENDSTOP_OPEN));
#endif
#if HAS_Z2_MAX
SERIAL_PROTOCOLPGM(MSG_Z2_MAX);
SERIAL_PROTOCOLLN(((READ(Z2_MAX_PIN)^Z2_MAX_ENDSTOP_INVERTING) ? MSG_ENDSTOP_HIT : MSG_ENDSTOP_OPEN));
#endif
#if HAS_Z_PROBE
SERIAL_PROTOCOLPGM(MSG_Z_PROBE);
SERIAL_PROTOCOLLN(((READ(Z_MIN_PROBE_PIN)^Z_MIN_PROBE_ENDSTOP_INVERTING) ? MSG_ENDSTOP_HIT : MSG_ENDSTOP_OPEN));
#endif
}
/**
* M120: Enable endstops and set non-homing endstop state to "enabled"
*/
inline void gcode_M120() { enable_endstops_globally(true); }
/**
* M121: Disable endstops and set non-homing endstop state to "disabled"
*/
inline void gcode_M121() { enable_endstops_globally(false); }
#if ENABLED(BLINKM)
/**
* M150: Set Status LED Color - Use R-U-B for R-G-B
*/
inline void gcode_M150() {
SendColors(
code_seen('R') ? (byte)code_value_short() : 0,
code_seen('U') ? (byte)code_value_short() : 0,
code_seen('B') ? (byte)code_value_short() : 0
);
}
#endif // BLINKM
/**
* M200: Set filament diameter and set E axis units to cubic millimeters
*
* T - Optional extruder number. Current extruder if omitted.
* D - Diameter of the filament. Use "D0" to set units back to millimeters.
*/
inline void gcode_M200() {
if (setTargetedHotend(200)) return;
if (code_seen('D')) {
float diameter = code_value();
// setting any extruder filament size disables volumetric on the assumption that
// slicers either generate in extruder values as cubic mm or as as filament feeds
// for all extruders
volumetric_enabled = (diameter != 0.0);
if (volumetric_enabled) {
filament_size[target_extruder] = diameter;
// make sure all extruders have some sane value for the filament size
for (int i = 0; i < EXTRUDERS; i++)
if (! filament_size[i]) filament_size[i] = DEFAULT_NOMINAL_FILAMENT_DIA;
}
}
else {
//reserved for setting filament diameter via UFID or filament measuring device
return;
}
calculate_volumetric_multipliers();
}
/**
* M201: Set max acceleration in units/s^2 for print moves (M201 X1000 Y1000)
*/
inline void gcode_M201() {
for (int8_t i = 0; i < NUM_AXIS; i++) {
if (code_seen(axis_codes[i])) {
max_acceleration_units_per_sq_second[i] = code_value();
}
}
// steps per sq second need to be updated to agree with the units per sq second (as they are what is used in the planner)
reset_acceleration_rates();
}
#if 0 // Not used for Sprinter/grbl gen6
inline void gcode_M202() {
for (int8_t i = 0; i < NUM_AXIS; i++) {
if (code_seen(axis_codes[i])) axis_travel_steps_per_sqr_second[i] = code_value() * axis_steps_per_unit[i];
}
}
#endif
/**
* M203: Set maximum feedrate that your machine can sustain (M203 X200 Y200 Z300 E10000) in mm/sec
*/
inline void gcode_M203() {
for (int8_t i = 0; i < NUM_AXIS; i++) {
if (code_seen(axis_codes[i])) {
max_feedrate[i] = code_value();
}
}
}
/**
* M204: Set Accelerations in mm/sec^2 (M204 P1200 R3000 T3000)
*
* P = Printing moves
* R = Retract only (no X, Y, Z) moves
* T = Travel (non printing) moves
*
* Also sets minimum segment time in ms (B20000) to prevent buffer under-runs and M20 minimum feedrate
*/
inline void gcode_M204() {
if (code_seen('S')) { // Kept for legacy compatibility. Should NOT BE USED for new developments.
travel_acceleration = acceleration = code_value();
SERIAL_ECHOPAIR("Setting Print and Travel Acceleration: ", acceleration);
SERIAL_EOL;
}
if (code_seen('P')) {
acceleration = code_value();
SERIAL_ECHOPAIR("Setting Print Acceleration: ", acceleration);
SERIAL_EOL;
}
if (code_seen('R')) {
retract_acceleration = code_value();
SERIAL_ECHOPAIR("Setting Retract Acceleration: ", retract_acceleration);
SERIAL_EOL;
}
if (code_seen('T')) {
travel_acceleration = code_value();
SERIAL_ECHOPAIR("Setting Travel Acceleration: ", travel_acceleration);
SERIAL_EOL;
}
}
/**
* M205: Set Advanced Settings
*
* S = Min Feed Rate (mm/s)
* T = Min Travel Feed Rate (mm/s)
* B = Min Segment Time (µs)
* X = Max XY Jerk (mm/s/s)
* Z = Max Z Jerk (mm/s/s)
* E = Max E Jerk (mm/s/s)
*/
inline void gcode_M205() {
if (code_seen('S')) minimumfeedrate = code_value();
if (code_seen('T')) mintravelfeedrate = code_value();
if (code_seen('B')) minsegmenttime = code_value();
if (code_seen('X')) max_xy_jerk = code_value();
if (code_seen('Z')) max_z_jerk = code_value();
if (code_seen('E')) max_e_jerk = code_value();
}
/**
* M206: Set Additional Homing Offset (X Y Z). SCARA aliases T=X, P=Y
*/
inline void gcode_M206() {
for (int8_t i = X_AXIS; i <= Z_AXIS; i++) {
if (code_seen(axis_codes[i])) {
home_offset[i] = code_value();
}
}
#if ENABLED(SCARA)
if (code_seen('T')) home_offset[X_AXIS] = code_value(); // Theta
if (code_seen('P')) home_offset[Y_AXIS] = code_value(); // Psi
#endif
}
#if ENABLED(DELTA)
/**
* M665: Set delta configurations
*
* L = diagonal rod
* R = delta radius
* S = segments per second
* A = Alpha (Tower 1) diagonal rod trim
* B = Beta (Tower 2) diagonal rod trim
* C = Gamma (Tower 3) diagonal rod trim
*/
inline void gcode_M665() {
if (code_seen('L')) delta_diagonal_rod = code_value();
if (code_seen('R')) delta_radius = code_value();
if (code_seen('S')) delta_segments_per_second = code_value();
if (code_seen('A')) delta_diagonal_rod_trim_tower_1 = code_value();
if (code_seen('B')) delta_diagonal_rod_trim_tower_2 = code_value();
if (code_seen('C')) delta_diagonal_rod_trim_tower_3 = code_value();
recalc_delta_settings(delta_radius, delta_diagonal_rod);
}
/**
* M666: Set delta endstop adjustment
*/
inline void gcode_M666() {
#if ENABLED(DEBUG_LEVELING_FEATURE)
if (DEBUGGING(LEVELING)) {
SERIAL_ECHOLNPGM(">>> gcode_M666");
}
#endif
for (int8_t i = X_AXIS; i <= Z_AXIS; i++) {
if (code_seen(axis_codes[i])) {
endstop_adj[i] = code_value();
#if ENABLED(DEBUG_LEVELING_FEATURE)
if (DEBUGGING(LEVELING)) {
SERIAL_ECHOPGM("endstop_adj[");
SERIAL_ECHO(axis_codes[i]);
SERIAL_ECHOPAIR("] = ", endstop_adj[i]);
SERIAL_EOL;
}
#endif
}
}
#if ENABLED(DEBUG_LEVELING_FEATURE)
if (DEBUGGING(LEVELING)) {
SERIAL_ECHOLNPGM("<<< gcode_M666");
}
#endif
}
#elif ENABLED(Z_DUAL_ENDSTOPS) // !DELTA && ENABLED(Z_DUAL_ENDSTOPS)
/**
* M666: For Z Dual Endstop setup, set z axis offset to the z2 axis.
*/
inline void gcode_M666() {
if (code_seen('Z')) z_endstop_adj = code_value();
SERIAL_ECHOPAIR("Z Endstop Adjustment set to (mm):", z_endstop_adj);
SERIAL_EOL;
}
#endif // !DELTA && Z_DUAL_ENDSTOPS
#if ENABLED(FWRETRACT)
/**
* M207: Set firmware retraction values
*
* S[+mm] retract_length
* W[+mm] retract_length_swap (multi-extruder)
* F[mm/min] retract_feedrate
* Z[mm] retract_zlift
*/
inline void gcode_M207() {
if (code_seen('S')) retract_length = code_value();
if (code_seen('F')) retract_feedrate = code_value() / 60;
if (code_seen('Z')) retract_zlift = code_value();
#if EXTRUDERS > 1
if (code_seen('W')) retract_length_swap = code_value();
#endif
}
/**
* M208: Set firmware un-retraction values
*
* S[+mm] retract_recover_length (in addition to M207 S*)
* W[+mm] retract_recover_length_swap (multi-extruder)
* F[mm/min] retract_recover_feedrate
*/
inline void gcode_M208() {
if (code_seen('S')) retract_recover_length = code_value();
if (code_seen('F')) retract_recover_feedrate = code_value() / 60;
#if EXTRUDERS > 1
if (code_seen('W')) retract_recover_length_swap = code_value();
#endif
}
/**
* M209: Enable automatic retract (M209 S1)
* detect if the slicer did not support G10/11: every normal extrude-only move will be classified as retract depending on the direction.
*/
inline void gcode_M209() {
if (code_seen('S')) {
int t = code_value_short();
switch (t) {
case 0:
autoretract_enabled = false;
break;
case 1:
autoretract_enabled = true;
break;
default:
unknown_command_error();
return;
}
for (int i = 0; i < EXTRUDERS; i++) retracted[i] = false;
}
}
#endif // FWRETRACT
#if EXTRUDERS > 1
/**
* M218 - set hotend offset (in mm), T X Y
*/
inline void gcode_M218() {
if (setTargetedHotend(218)) return;
if (code_seen('X')) extruder_offset[X_AXIS][target_extruder] = code_value();
if (code_seen('Y')) extruder_offset[Y_AXIS][target_extruder] = code_value();
#if ENABLED(DUAL_X_CARRIAGE)
if (code_seen('Z')) extruder_offset[Z_AXIS][target_extruder] = code_value();
#endif
SERIAL_ECHO_START;
SERIAL_ECHOPGM(MSG_HOTEND_OFFSET);
for (int e = 0; e < EXTRUDERS; e++) {
SERIAL_CHAR(' ');
SERIAL_ECHO(extruder_offset[X_AXIS][e]);
SERIAL_CHAR(',');
SERIAL_ECHO(extruder_offset[Y_AXIS][e]);
#if ENABLED(DUAL_X_CARRIAGE)
SERIAL_CHAR(',');
SERIAL_ECHO(extruder_offset[Z_AXIS][e]);
#endif
}
SERIAL_EOL;
}
#endif // EXTRUDERS > 1
/**
* M220: Set speed percentage factor, aka "Feed Rate" (M220 S95)
*/
inline void gcode_M220() {
if (code_seen('S')) feedrate_multiplier = code_value();
}
/**
* M221: Set extrusion percentage (M221 T0 S95)
*/
inline void gcode_M221() {
if (code_seen('S')) {
int sval = code_value();
if (setTargetedHotend(221)) return;
extruder_multiplier[target_extruder] = sval;
}
}
/**
* M226: Wait until the specified pin reaches the state required (M226 P S)
*/
inline void gcode_M226() {
if (code_seen('P')) {
int pin_number = code_value();
int pin_state = code_seen('S') ? code_value() : -1; // required pin state - default is inverted
if (pin_state >= -1 && pin_state <= 1) {
for (uint8_t i = 0; i < COUNT(sensitive_pins); i++) {
if (sensitive_pins[i] == pin_number) {
pin_number = -1;
break;
}
}
if (pin_number > -1) {
int target = LOW;
st_synchronize();
pinMode(pin_number, INPUT);
switch (pin_state) {
case 1:
target = HIGH;
break;
case 0:
target = LOW;
break;
case -1:
target = !digitalRead(pin_number);
break;
}
while (digitalRead(pin_number) != target) idle();
} // pin_number > -1
} // pin_state -1 0 1
} // code_seen('P')
}
#if HAS_SERVOS
/**
* M280: Get or set servo position. P S
*/
inline void gcode_M280() {
int servo_index = code_seen('P') ? code_value_short() : -1;
int servo_position = 0;
if (code_seen('S')) {
servo_position = code_value_short();
if (servo_index >= 0 && servo_index < NUM_SERVOS)
servo[servo_index].move(servo_position);
else {
SERIAL_ERROR_START;
SERIAL_ERROR("Servo ");
SERIAL_ERROR(servo_index);
SERIAL_ERRORLN(" out of range");
}
}
else if (servo_index >= 0) {
SERIAL_ECHO_START;
SERIAL_ECHO(" Servo ");
SERIAL_ECHO(servo_index);
SERIAL_ECHO(": ");
SERIAL_ECHOLN(servo[servo_index].read());
}
}
#endif // HAS_SERVOS
#if HAS_BUZZER
/**
* M300: Play beep sound S P
*/
inline void gcode_M300() {
uint16_t beepS = code_seen('S') ? code_value_short() : 110;
uint32_t beepP = code_seen('P') ? code_value_long() : 1000;
if (beepP > 5000) beepP = 5000; // limit to 5 seconds
buzz(beepP, beepS);
}
#endif // HAS_BUZZER
#if ENABLED(PIDTEMP)
/**
* M301: Set PID parameters P I D (and optionally C, L)
*
* P[float] Kp term
* I[float] Ki term (unscaled)
* D[float] Kd term (unscaled)
*
* With PID_ADD_EXTRUSION_RATE:
*
* C[float] Kc term
* L[float] LPQ length
*/
inline void gcode_M301() {
// multi-extruder PID patch: M301 updates or prints a single extruder's PID values
// default behaviour (omitting E parameter) is to update for extruder 0 only
int e = code_seen('E') ? code_value() : 0; // extruder being updated
if (e < EXTRUDERS) { // catch bad input value
if (code_seen('P')) PID_PARAM(Kp, e) = code_value();
if (code_seen('I')) PID_PARAM(Ki, e) = scalePID_i(code_value());
if (code_seen('D')) PID_PARAM(Kd, e) = scalePID_d(code_value());
#if ENABLED(PID_ADD_EXTRUSION_RATE)
if (code_seen('C')) PID_PARAM(Kc, e) = code_value();
if (code_seen('L')) lpq_len = code_value();
NOMORE(lpq_len, LPQ_MAX_LEN);
#endif
updatePID();
SERIAL_ECHO_START;
#if ENABLED(PID_PARAMS_PER_EXTRUDER)
SERIAL_ECHO(" e:"); // specify extruder in serial output
SERIAL_ECHO(e);
#endif // PID_PARAMS_PER_EXTRUDER
SERIAL_ECHO(" p:");
SERIAL_ECHO(PID_PARAM(Kp, e));
SERIAL_ECHO(" i:");
SERIAL_ECHO(unscalePID_i(PID_PARAM(Ki, e)));
SERIAL_ECHO(" d:");
SERIAL_ECHO(unscalePID_d(PID_PARAM(Kd, e)));
#if ENABLED(PID_ADD_EXTRUSION_RATE)
SERIAL_ECHO(" c:");
//Kc does not have scaling applied above, or in resetting defaults
SERIAL_ECHO(PID_PARAM(Kc, e));
#endif
SERIAL_EOL;
}
else {
SERIAL_ERROR_START;
SERIAL_ERRORLN(MSG_INVALID_EXTRUDER);
}
}
#endif // PIDTEMP
#if ENABLED(PIDTEMPBED)
inline void gcode_M304() {
if (code_seen('P')) bedKp = code_value();
if (code_seen('I')) bedKi = scalePID_i(code_value());
if (code_seen('D')) bedKd = scalePID_d(code_value());
updatePID();
SERIAL_ECHO_START;
SERIAL_ECHO(" p:");
SERIAL_ECHO(bedKp);
SERIAL_ECHO(" i:");
SERIAL_ECHO(unscalePID_i(bedKi));
SERIAL_ECHO(" d:");
SERIAL_ECHOLN(unscalePID_d(bedKd));
}
#endif // PIDTEMPBED
#if defined(CHDK) || HAS_PHOTOGRAPH
/**
* M240: Trigger a camera by emulating a Canon RC-1
* See http://www.doc-diy.net/photo/rc-1_hacked/
*/
inline void gcode_M240() {
#ifdef CHDK
OUT_WRITE(CHDK, HIGH);
chdkHigh = millis();
chdkActive = true;
#elif HAS_PHOTOGRAPH
const uint8_t NUM_PULSES = 16;
const float PULSE_LENGTH = 0.01524;
for (int i = 0; i < NUM_PULSES; i++) {
WRITE(PHOTOGRAPH_PIN, HIGH);
_delay_ms(PULSE_LENGTH);
WRITE(PHOTOGRAPH_PIN, LOW);
_delay_ms(PULSE_LENGTH);
}
delay(7.33);
for (int i = 0; i < NUM_PULSES; i++) {
WRITE(PHOTOGRAPH_PIN, HIGH);
_delay_ms(PULSE_LENGTH);
WRITE(PHOTOGRAPH_PIN, LOW);
_delay_ms(PULSE_LENGTH);
}
#endif // !CHDK && HAS_PHOTOGRAPH
}
#endif // CHDK || PHOTOGRAPH_PIN
#if ENABLED(HAS_LCD_CONTRAST)
/**
* M250: Read and optionally set the LCD contrast
*/
inline void gcode_M250() {
if (code_seen('C')) lcd_setcontrast(code_value_short() & 0x3F);
SERIAL_PROTOCOLPGM("lcd contrast value: ");
SERIAL_PROTOCOL(lcd_contrast);
SERIAL_EOL;
}
#endif // HAS_LCD_CONTRAST
#if ENABLED(PREVENT_DANGEROUS_EXTRUDE)
void set_extrude_min_temp(float temp) { extrude_min_temp = temp; }
/**
* M302: Allow cold extrudes, or set the minimum extrude S.
*/
inline void gcode_M302() {
set_extrude_min_temp(code_seen('S') ? code_value() : 0);
}
#endif // PREVENT_DANGEROUS_EXTRUDE
/**
* M303: PID relay autotune
*
* S sets the target temperature. (default 150C)
* E (-1 for the bed) (default 0)
* C
* U with a non-zero value will apply the result to current settings
*/
inline void gcode_M303() {
int e = code_seen('E') ? code_value_short() : 0;
int c = code_seen('C') ? code_value_short() : 5;
bool u = code_seen('U') && code_value_short() != 0;
float temp = code_seen('S') ? code_value() : (e < 0 ? 70.0 : 150.0);
if (e >= 0 && e < EXTRUDERS)
target_extruder = e;
KEEPALIVE_STATE(NOT_BUSY); // don't send "busy: processing" messages during autotune output
PID_autotune(temp, e, c, u);
KEEPALIVE_STATE(IN_HANDLER);
}
#if ENABLED(SCARA)
bool SCARA_move_to_cal(uint8_t delta_x, uint8_t delta_y) {
//SoftEndsEnabled = false; // Ignore soft endstops during calibration
//SERIAL_ECHOLN(" Soft endstops disabled ");
if (IsRunning()) {
//gcode_get_destination(); // For X Y Z E F
delta[X_AXIS] = delta_x;
delta[Y_AXIS] = delta_y;
calculate_SCARA_forward_Transform(delta);
destination[X_AXIS] = delta[X_AXIS] / axis_scaling[X_AXIS];
destination[Y_AXIS] = delta[Y_AXIS] / axis_scaling[Y_AXIS];
prepare_move();
//ok_to_send();
return true;
}
return false;
}
/**
* M360: SCARA calibration: Move to cal-position ThetaA (0 deg calibration)
*/
inline bool gcode_M360() {
SERIAL_ECHOLN(" Cal: Theta 0 ");
return SCARA_move_to_cal(0, 120);
}
/**
* M361: SCARA calibration: Move to cal-position ThetaB (90 deg calibration - steps per degree)
*/
inline bool gcode_M361() {
SERIAL_ECHOLN(" Cal: Theta 90 ");
return SCARA_move_to_cal(90, 130);
}
/**
* M362: SCARA calibration: Move to cal-position PsiA (0 deg calibration)
*/
inline bool gcode_M362() {
SERIAL_ECHOLN(" Cal: Psi 0 ");
return SCARA_move_to_cal(60, 180);
}
/**
* M363: SCARA calibration: Move to cal-position PsiB (90 deg calibration - steps per degree)
*/
inline bool gcode_M363() {
SERIAL_ECHOLN(" Cal: Psi 90 ");
return SCARA_move_to_cal(50, 90);
}
/**
* M364: SCARA calibration: Move to cal-position PSIC (90 deg to Theta calibration position)
*/
inline bool gcode_M364() {
SERIAL_ECHOLN(" Cal: Theta-Psi 90 ");
return SCARA_move_to_cal(45, 135);
}
/**
* M365: SCARA calibration: Scaling factor, X, Y, Z axis
*/
inline void gcode_M365() {
for (int8_t i = X_AXIS; i <= Z_AXIS; i++) {
if (code_seen(axis_codes[i])) {
axis_scaling[i] = code_value();
}
}
}
#endif // SCARA
#if ENABLED(EXT_SOLENOID)
void enable_solenoid(uint8_t num) {
switch (num) {
case 0:
OUT_WRITE(SOL0_PIN, HIGH);
break;
#if HAS_SOLENOID_1
case 1:
OUT_WRITE(SOL1_PIN, HIGH);
break;
#endif
#if HAS_SOLENOID_2
case 2:
OUT_WRITE(SOL2_PIN, HIGH);
break;
#endif
#if HAS_SOLENOID_3
case 3:
OUT_WRITE(SOL3_PIN, HIGH);
break;
#endif
default:
SERIAL_ECHO_START;
SERIAL_ECHOLNPGM(MSG_INVALID_SOLENOID);
break;
}
}
void enable_solenoid_on_active_extruder() { enable_solenoid(active_extruder); }
void disable_all_solenoids() {
OUT_WRITE(SOL0_PIN, LOW);
OUT_WRITE(SOL1_PIN, LOW);
OUT_WRITE(SOL2_PIN, LOW);
OUT_WRITE(SOL3_PIN, LOW);
}
/**
* M380: Enable solenoid on the active extruder
*/
inline void gcode_M380() { enable_solenoid_on_active_extruder(); }
/**
* M381: Disable all solenoids
*/
inline void gcode_M381() { disable_all_solenoids(); }
#endif // EXT_SOLENOID
/**
* M400: Finish all moves
*/
inline void gcode_M400() { st_synchronize(); }
#if ENABLED(AUTO_BED_LEVELING_FEATURE) && DISABLED(Z_PROBE_SLED) && (HAS_SERVO_ENDSTOPS || ENABLED(Z_PROBE_ALLEN_KEY))
/**
* M401: Engage Z Servo endstop if available
*/
inline void gcode_M401() {
#if HAS_SERVO_ENDSTOPS
raise_z_for_servo();
#endif
deploy_z_probe();
}
/**
* M402: Retract Z Servo endstop if enabled
*/
inline void gcode_M402() {
#if HAS_SERVO_ENDSTOPS
raise_z_for_servo();
#endif
stow_z_probe(false);
}
#endif // AUTO_BED_LEVELING_FEATURE && (HAS_SERVO_ENDSTOPS || Z_PROBE_ALLEN_KEY) && !Z_PROBE_SLED
#if ENABLED(FILAMENT_WIDTH_SENSOR)
/**
* M404: Display or set the nominal filament width (3mm, 1.75mm ) W<3.0>
*/
inline void gcode_M404() {
if (code_seen('W')) {
filament_width_nominal = code_value();
}
else {
SERIAL_PROTOCOLPGM("Filament dia (nominal mm):");
SERIAL_PROTOCOLLN(filament_width_nominal);
}
}
/**
* M405: Turn on filament sensor for control
*/
inline void gcode_M405() {
if (code_seen('D')) meas_delay_cm = code_value();
NOMORE(meas_delay_cm, MAX_MEASUREMENT_DELAY);
if (delay_index2 == -1) { //initialize the ring buffer if it has not been done since startup
int temp_ratio = widthFil_to_size_ratio();
for (delay_index1 = 0; delay_index1 < (int)COUNT(measurement_delay); ++delay_index1)
measurement_delay[delay_index1] = temp_ratio - 100; //subtract 100 to scale within a signed byte
delay_index1 = delay_index2 = 0;
}
filament_sensor = true;
//SERIAL_PROTOCOLPGM("Filament dia (measured mm):");
//SERIAL_PROTOCOL(filament_width_meas);
//SERIAL_PROTOCOLPGM("Extrusion ratio(%):");
//SERIAL_PROTOCOL(extruder_multiplier[active_extruder]);
}
/**
* M406: Turn off filament sensor for control
*/
inline void gcode_M406() { filament_sensor = false; }
/**
* M407: Get measured filament diameter on serial output
*/
inline void gcode_M407() {
SERIAL_PROTOCOLPGM("Filament dia (measured mm):");
SERIAL_PROTOCOLLN(filament_width_meas);
}
#endif // FILAMENT_WIDTH_SENSOR
/**
* M410: Quickstop - Abort all planned moves
*
* This will stop the carriages mid-move, so most likely they
* will be out of sync with the stepper position after this.
*/
inline void gcode_M410() { quickStop(); }
#if ENABLED(MESH_BED_LEVELING)
/**
* M420: Enable/Disable Mesh Bed Leveling
*/
inline void gcode_M420() { if (code_seen('S') && code_has_value()) mbl.active = !!code_value_short(); }
/**
* M421: Set a single Mesh Bed Leveling Z coordinate
*/
inline void gcode_M421() {
float x = 0, y = 0, z = 0;
bool err = false, hasX, hasY, hasZ;
if ((hasX = code_seen('X'))) x = code_value();
if ((hasY = code_seen('Y'))) y = code_value();
if ((hasZ = code_seen('Z'))) z = code_value();
if (!hasX || !hasY || !hasZ) {
SERIAL_ERROR_START;
SERIAL_ERRORLNPGM(MSG_ERR_M421_REQUIRES_XYZ);
err = true;
}
if (x >= MESH_NUM_X_POINTS || y >= MESH_NUM_Y_POINTS) {
SERIAL_ERROR_START;
SERIAL_ERRORLNPGM(MSG_ERR_MESH_INDEX_OOB);
err = true;
}
if (!err) mbl.set_z(mbl.select_x_index(x), mbl.select_y_index(y), z);
}
#endif
/**
* M428: Set home_offset based on the distance between the
* current_position and the nearest "reference point."
* If an axis is past center its endstop position
* is the reference-point. Otherwise it uses 0. This allows
* the Z offset to be set near the bed when using a max endstop.
*
* M428 can't be used more than 2cm away from 0 or an endstop.
*
* Use M206 to set these values directly.
*/
inline void gcode_M428() {
bool err = false;
float new_offs[3], new_pos[3];
memcpy(new_pos, current_position, sizeof(new_pos));
memcpy(new_offs, home_offset, sizeof(new_offs));
for (int8_t i = X_AXIS; i <= Z_AXIS; i++) {
if (axis_homed[i]) {
float base = (new_pos[i] > (min_pos[i] + max_pos[i]) / 2) ? base_home_pos(i) : 0,
diff = new_pos[i] - base;
if (diff > -20 && diff < 20) {
new_offs[i] -= diff;
new_pos[i] = base;
}
else {
SERIAL_ERROR_START;
SERIAL_ERRORLNPGM(MSG_ERR_M428_TOO_FAR);
LCD_ALERTMESSAGEPGM("Err: Too far!");
#if HAS_BUZZER
buzz(200, 40);
#endif
err = true;
break;
}
}
}
if (!err) {
memcpy(current_position, new_pos, sizeof(new_pos));
memcpy(home_offset, new_offs, sizeof(new_offs));
sync_plan_position();
LCD_ALERTMESSAGEPGM(MSG_HOME_OFFSETS_APPLIED);
#if HAS_BUZZER
buzz(200, 659);
buzz(200, 698);
#endif
}
}
/**
* M500: Store settings in EEPROM
*/
inline void gcode_M500() {
Config_StoreSettings();
}
/**
* M501: Read settings from EEPROM
*/
inline void gcode_M501() {
Config_RetrieveSettings();
}
/**
* M502: Revert to default settings
*/
inline void gcode_M502() {
Config_ResetDefault();
}
/**
* M503: print settings currently in memory
*/
inline void gcode_M503() {
Config_PrintSettings(code_seen('S') && code_value() == 0);
}
#if ENABLED(ABORT_ON_ENDSTOP_HIT_FEATURE_ENABLED)
/**
* M540: Set whether SD card print should abort on endstop hit (M540 S<0|1>)
*/
inline void gcode_M540() {
if (code_seen('S')) abort_on_endstop_hit = (code_value() > 0);
}
#endif // ABORT_ON_ENDSTOP_HIT_FEATURE_ENABLED
#ifdef CUSTOM_M_CODE_SET_Z_PROBE_OFFSET
inline void gcode_SET_Z_PROBE_OFFSET() {
SERIAL_ECHO_START;
SERIAL_ECHOPGM(MSG_ZPROBE_ZOFFSET);
SERIAL_CHAR(' ');
if (code_seen('Z')) {
float value = code_value();
if (Z_PROBE_OFFSET_RANGE_MIN <= value && value <= Z_PROBE_OFFSET_RANGE_MAX) {
zprobe_zoffset = value;
SERIAL_ECHO(zprobe_zoffset);
}
else {
SERIAL_ECHOPGM(MSG_Z_MIN);
SERIAL_ECHO(Z_PROBE_OFFSET_RANGE_MIN);
SERIAL_ECHOPGM(MSG_Z_MAX);
SERIAL_ECHO(Z_PROBE_OFFSET_RANGE_MAX);
}
}
else {
SERIAL_ECHOPAIR(": ", zprobe_zoffset);
}
SERIAL_EOL;
}
#endif // CUSTOM_M_CODE_SET_Z_PROBE_OFFSET
#if ENABLED(FILAMENTCHANGEENABLE)
/**
* M600: Pause for filament change
*
* E[distance] - Retract the filament this far (negative value)
* Z[distance] - Move the Z axis by this distance
* X[position] - Move to this X position, with Y
* Y[position] - Move to this Y position, with X
* L[distance] - Retract distance for removal (manual reload)
*
* Default values are used for omitted arguments.
*
*/
inline void gcode_M600() {
if (degHotend(active_extruder) < extrude_min_temp) {
SERIAL_ERROR_START;
SERIAL_ERRORLNPGM(MSG_TOO_COLD_FOR_M600);
return;
}
float lastpos[NUM_AXIS];
#if ENABLED(DELTA)
float fr60 = feedrate / 60;
#endif
for (int i = 0; i < NUM_AXIS; i++)
lastpos[i] = destination[i] = current_position[i];
#if ENABLED(DELTA)
#define RUNPLAN calculate_delta(destination); \
plan_buffer_line(delta[X_AXIS], delta[Y_AXIS], delta[Z_AXIS], destination[E_AXIS], fr60, active_extruder);
#else
#define RUNPLAN line_to_destination();
#endif
//retract by E
if (code_seen('E')) destination[E_AXIS] += code_value();
#ifdef FILAMENTCHANGE_FIRSTRETRACT
else destination[E_AXIS] += FILAMENTCHANGE_FIRSTRETRACT;
#endif
RUNPLAN;
//lift Z
if (code_seen('Z')) destination[Z_AXIS] += code_value();
#ifdef FILAMENTCHANGE_ZADD
else destination[Z_AXIS] += FILAMENTCHANGE_ZADD;
#endif
RUNPLAN;
//move xy
if (code_seen('X')) destination[X_AXIS] = code_value();
#ifdef FILAMENTCHANGE_XPOS
else destination[X_AXIS] = FILAMENTCHANGE_XPOS;
#endif
if (code_seen('Y')) destination[Y_AXIS] = code_value();
#ifdef FILAMENTCHANGE_YPOS
else destination[Y_AXIS] = FILAMENTCHANGE_YPOS;
#endif
RUNPLAN;
if (code_seen('L')) destination[E_AXIS] += code_value();
#ifdef FILAMENTCHANGE_FINALRETRACT
else destination[E_AXIS] += FILAMENTCHANGE_FINALRETRACT;
#endif
RUNPLAN;
//finish moves
st_synchronize();
//disable extruder steppers so filament can be removed
disable_e0();
disable_e1();
disable_e2();
disable_e3();
delay(100);
LCD_ALERTMESSAGEPGM(MSG_FILAMENTCHANGE);
#if DISABLED(AUTO_FILAMENT_CHANGE)
millis_t next_tick = 0;
#endif
KEEPALIVE_STATE(PAUSED_FOR_USER);
while (!lcd_clicked()) {
#if DISABLED(AUTO_FILAMENT_CHANGE)
millis_t ms = millis();
if (ms >= next_tick) {
lcd_quick_feedback();
next_tick = ms + 2500; // feedback every 2.5s while waiting
}
idle(true);
#else
current_position[E_AXIS] += AUTO_FILAMENT_CHANGE_LENGTH;
destination[E_AXIS] = current_position[E_AXIS];
line_to_destination(AUTO_FILAMENT_CHANGE_FEEDRATE);
st_synchronize();
#endif
} // while(!lcd_clicked)
KEEPALIVE_STATE(IN_HANDLER);
lcd_quick_feedback(); // click sound feedback
#if ENABLED(AUTO_FILAMENT_CHANGE)
current_position[E_AXIS] = 0;
st_synchronize();
#endif
//return to normal
if (code_seen('L')) destination[E_AXIS] -= code_value();
#ifdef FILAMENTCHANGE_FINALRETRACT
else destination[E_AXIS] -= FILAMENTCHANGE_FINALRETRACT;
#endif
current_position[E_AXIS] = destination[E_AXIS]; //the long retract of L is compensated by manual filament feeding
plan_set_e_position(current_position[E_AXIS]);
RUNPLAN; //should do nothing
lcd_reset_alert_level();
#if ENABLED(DELTA)
// Move XYZ to starting position, then E
calculate_delta(lastpos);
plan_buffer_line(delta[X_AXIS], delta[Y_AXIS], delta[Z_AXIS], destination[E_AXIS], fr60, active_extruder);
plan_buffer_line(delta[X_AXIS], delta[Y_AXIS], delta[Z_AXIS], lastpos[E_AXIS], fr60, active_extruder);
#else
// Move XY to starting position, then Z, then E
destination[X_AXIS] = lastpos[X_AXIS];
destination[Y_AXIS] = lastpos[Y_AXIS];
line_to_destination();
destination[Z_AXIS] = lastpos[Z_AXIS];
line_to_destination();
destination[E_AXIS] = lastpos[E_AXIS];
line_to_destination();
#endif
#if ENABLED(FILAMENT_RUNOUT_SENSOR)
filrunoutEnqueued = false;
#endif
}
#endif // FILAMENTCHANGEENABLE
#if ENABLED(DUAL_X_CARRIAGE)
/**
* M605: Set dual x-carriage movement mode
*
* M605 S0: Full control mode. The slicer has full control over x-carriage movement
* M605 S1: Auto-park mode. The inactive head will auto park/unpark without slicer involvement
* M605 S2 [Xnnn] [Rmmm]: Duplication mode. The second extruder will duplicate the first with nnn
* millimeters x-offset and an optional differential hotend temperature of
* mmm degrees. E.g., with "M605 S2 X100 R2" the second extruder will duplicate
* the first with a spacing of 100mm in the x direction and 2 degrees hotter.
*
* Note: the X axis should be homed after changing dual x-carriage mode.
*/
inline void gcode_M605() {
st_synchronize();
if (code_seen('S')) dual_x_carriage_mode = code_value();
switch (dual_x_carriage_mode) {
case DXC_DUPLICATION_MODE:
if (code_seen('X')) duplicate_extruder_x_offset = max(code_value(), X2_MIN_POS - x_home_pos(0));
if (code_seen('R')) duplicate_extruder_temp_offset = code_value();
SERIAL_ECHO_START;
SERIAL_ECHOPGM(MSG_HOTEND_OFFSET);
SERIAL_CHAR(' ');
SERIAL_ECHO(extruder_offset[X_AXIS][0]);
SERIAL_CHAR(',');
SERIAL_ECHO(extruder_offset[Y_AXIS][0]);
SERIAL_CHAR(' ');
SERIAL_ECHO(duplicate_extruder_x_offset);
SERIAL_CHAR(',');
SERIAL_ECHOLN(extruder_offset[Y_AXIS][1]);
break;
case DXC_FULL_CONTROL_MODE:
case DXC_AUTO_PARK_MODE:
break;
default:
dual_x_carriage_mode = DEFAULT_DUAL_X_CARRIAGE_MODE;
break;
}
active_extruder_parked = false;
extruder_duplication_enabled = false;
delayed_move_time = 0;
}
#endif // DUAL_X_CARRIAGE
/**
* M907: Set digital trimpot motor current using axis codes X, Y, Z, E, B, S
*/
inline void gcode_M907() {
#if HAS_DIGIPOTSS
for (int i = 0; i < NUM_AXIS; i++)
if (code_seen(axis_codes[i])) digipot_current(i, code_value());
if (code_seen('B')) digipot_current(4, code_value());
if (code_seen('S')) for (int i = 0; i <= 4; i++) digipot_current(i, code_value());
#endif
#if PIN_EXISTS(MOTOR_CURRENT_PWM_XY)
if (code_seen('X')) digipot_current(0, code_value());
#endif
#if PIN_EXISTS(MOTOR_CURRENT_PWM_Z)
if (code_seen('Z')) digipot_current(1, code_value());
#endif
#if PIN_EXISTS(MOTOR_CURRENT_PWM_E)
if (code_seen('E')) digipot_current(2, code_value());
#endif
#if ENABLED(DIGIPOT_I2C)
// this one uses actual amps in floating point
for (int i = 0; i < NUM_AXIS; i++) if (code_seen(axis_codes[i])) digipot_i2c_set_current(i, code_value());
// for each additional extruder (named B,C,D,E..., channels 4,5,6,7...)
for (int i = NUM_AXIS; i < DIGIPOT_I2C_NUM_CHANNELS; i++) if (code_seen('B' + i - (NUM_AXIS))) digipot_i2c_set_current(i, code_value());
#endif
#if ENABLED(DAC_STEPPER_CURRENT)
if (code_seen('S')) {
float dac_percent = code_value();
for (uint8_t i = 0; i <= 4; i++) dac_current_percent(i, dac_percent);
}
for (uint8_t i = 0; i < NUM_AXIS; i++) if (code_seen(axis_codes[i])) dac_current_percent(i, code_value());
#endif
}
#if HAS_DIGIPOTSS || ENABLED(DAC_STEPPER_CURRENT)
/**
* M908: Control digital trimpot directly (M908 P S)
*/
inline void gcode_M908() {
#if HAS_DIGIPOTSS
digitalPotWrite(
code_seen('P') ? code_value() : 0,
code_seen('S') ? code_value() : 0
);
#endif
#ifdef DAC_STEPPER_CURRENT
dac_current_raw(
code_seen('P') ? code_value_long() : -1,
code_seen('S') ? code_value_short() : 0
);
#endif
}
#if ENABLED(DAC_STEPPER_CURRENT) // As with Printrbot RevF
inline void gcode_M909() { dac_print_values(); }
inline void gcode_M910() { dac_commit_eeprom(); }
#endif
#endif // HAS_DIGIPOTSS || DAC_STEPPER_CURRENT
#if HAS_MICROSTEPS
// M350 Set microstepping mode. Warning: Steps per unit remains unchanged. S code sets stepping mode for all drivers.
inline void gcode_M350() {
if (code_seen('S')) for (int i = 0; i <= 4; i++) microstep_mode(i, code_value());
for (int i = 0; i < NUM_AXIS; i++) if (code_seen(axis_codes[i])) microstep_mode(i, (uint8_t)code_value());
if (code_seen('B')) microstep_mode(4, code_value());
microstep_readings();
}
/**
* M351: Toggle MS1 MS2 pins directly with axis codes X Y Z E B
* S# determines MS1 or MS2, X# sets the pin high/low.
*/
inline void gcode_M351() {
if (code_seen('S')) switch (code_value_short()) {
case 1:
for (int i = 0; i < NUM_AXIS; i++) if (code_seen(axis_codes[i])) microstep_ms(i, code_value(), -1);
if (code_seen('B')) microstep_ms(4, code_value(), -1);
break;
case 2:
for (int i = 0; i < NUM_AXIS; i++) if (code_seen(axis_codes[i])) microstep_ms(i, -1, code_value());
if (code_seen('B')) microstep_ms(4, -1, code_value());
break;
}
microstep_readings();
}
#endif // HAS_MICROSTEPS
/**
* M999: Restart after being stopped
*/
inline void gcode_M999() {
Running = true;
lcd_reset_alert_level();
// gcode_LastN = Stopped_gcode_LastN;
FlushSerialRequestResend();
}
/**
* T0-T3: Switch tool, usually switching extruders
*
* F[mm/min] Set the movement feedrate
*/
inline void gcode_T(uint8_t tmp_extruder) {
if (tmp_extruder >= EXTRUDERS) {
SERIAL_ECHO_START;
SERIAL_CHAR('T');
SERIAL_PROTOCOL_F(tmp_extruder, DEC);
SERIAL_ECHOLN(MSG_INVALID_EXTRUDER);
}
else {
target_extruder = tmp_extruder;
#if EXTRUDERS > 1
bool make_move = false;
#endif
if (code_seen('F')) {
#if EXTRUDERS > 1
make_move = true;
#endif
float next_feedrate = code_value();
if (next_feedrate > 0.0) feedrate = next_feedrate;
}
#if EXTRUDERS > 1
if (tmp_extruder != active_extruder) {
// Save current position to return to after applying extruder offset
set_destination_to_current();
#if ENABLED(DUAL_X_CARRIAGE)
if (dual_x_carriage_mode == DXC_AUTO_PARK_MODE && IsRunning() &&
(delayed_move_time != 0 || current_position[X_AXIS] != x_home_pos(active_extruder))) {
// Park old head: 1) raise 2) move to park position 3) lower
plan_buffer_line(current_position[X_AXIS], current_position[Y_AXIS], current_position[Z_AXIS] + TOOLCHANGE_PARK_ZLIFT,
current_position[E_AXIS], max_feedrate[Z_AXIS], active_extruder);
plan_buffer_line(x_home_pos(active_extruder), current_position[Y_AXIS], current_position[Z_AXIS] + TOOLCHANGE_PARK_ZLIFT,
current_position[E_AXIS], max_feedrate[X_AXIS], active_extruder);
plan_buffer_line(x_home_pos(active_extruder), current_position[Y_AXIS], current_position[Z_AXIS],
current_position[E_AXIS], max_feedrate[Z_AXIS], active_extruder);
st_synchronize();
}
// apply Y & Z extruder offset (x offset is already used in determining home pos)
current_position[Y_AXIS] -= extruder_offset[Y_AXIS][active_extruder] - extruder_offset[Y_AXIS][tmp_extruder];
current_position[Z_AXIS] -= extruder_offset[Z_AXIS][active_extruder] - extruder_offset[Z_AXIS][tmp_extruder];
active_extruder = tmp_extruder;
// This function resets the max/min values - the current position may be overwritten below.
set_axis_is_at_home(X_AXIS);
if (dual_x_carriage_mode == DXC_FULL_CONTROL_MODE) {
current_position[X_AXIS] = inactive_extruder_x_pos;
inactive_extruder_x_pos = destination[X_AXIS];
}
else if (dual_x_carriage_mode == DXC_DUPLICATION_MODE) {
active_extruder_parked = (active_extruder == 0); // this triggers the second extruder to move into the duplication position
if (active_extruder == 0 || active_extruder_parked)
current_position[X_AXIS] = inactive_extruder_x_pos;
else
current_position[X_AXIS] = destination[X_AXIS] + duplicate_extruder_x_offset;
inactive_extruder_x_pos = destination[X_AXIS];
extruder_duplication_enabled = false;
}
else {
// record raised toolhead position for use by unpark
memcpy(raised_parked_position, current_position, sizeof(raised_parked_position));
raised_parked_position[Z_AXIS] += TOOLCHANGE_UNPARK_ZLIFT;
active_extruder_parked = true;
delayed_move_time = 0;
}
#else // !DUAL_X_CARRIAGE
#if ENABLED(AUTO_BED_LEVELING_FEATURE)
// Offset extruder, make sure to apply the bed level rotation matrix
vector_3 tmp_offset_vec = vector_3(extruder_offset[X_AXIS][tmp_extruder],
extruder_offset[Y_AXIS][tmp_extruder],
extruder_offset[Z_AXIS][tmp_extruder]),
act_offset_vec = vector_3(extruder_offset[X_AXIS][active_extruder],
extruder_offset[Y_AXIS][active_extruder],
extruder_offset[Z_AXIS][active_extruder]),
offset_vec = tmp_offset_vec - act_offset_vec;
offset_vec.apply_rotation(plan_bed_level_matrix.transpose(plan_bed_level_matrix));
current_position[X_AXIS] += offset_vec.x;
current_position[Y_AXIS] += offset_vec.y;
current_position[Z_AXIS] += offset_vec.z;
#else // !AUTO_BED_LEVELING_FEATURE
// Offset extruder (only by XY)
for (int i=X_AXIS; i<=Y_AXIS; i++)
current_position[i] += extruder_offset[i][tmp_extruder] - extruder_offset[i][active_extruder];
#endif // !AUTO_BED_LEVELING_FEATURE
// Set the new active extruder and position
active_extruder = tmp_extruder;
#endif // !DUAL_X_CARRIAGE
#if ENABLED(DELTA)
sync_plan_position_delta();
#else
sync_plan_position();
#endif
// Move to the old position if 'F' was in the parameters
if (make_move && IsRunning()) prepare_move();
}
#if ENABLED(EXT_SOLENOID)
st_synchronize();
disable_all_solenoids();
enable_solenoid_on_active_extruder();
#endif // EXT_SOLENOID
#endif // EXTRUDERS > 1
SERIAL_ECHO_START;
SERIAL_ECHO(MSG_ACTIVE_EXTRUDER);
SERIAL_PROTOCOLLN((int)active_extruder);
}
}
/**
* Process a single command and dispatch it to its handler
* This is called from the main loop()
*/
void process_next_command() {
current_command = command_queue[cmd_queue_index_r];
if (DEBUGGING(ECHO)) {
SERIAL_ECHO_START;
SERIAL_ECHOLN(current_command);
}
// Sanitize the current command:
// - Skip leading spaces
// - Bypass N[-0-9][0-9]*[ ]*
// - Overwrite * with nul to mark the end
while (*current_command == ' ') ++current_command;
if (*current_command == 'N' && NUMERIC_SIGNED(current_command[1])) {
current_command += 2; // skip N[-0-9]
while (NUMERIC(*current_command)) ++current_command; // skip [0-9]*
while (*current_command == ' ') ++current_command; // skip [ ]*
}
char* starpos = strchr(current_command, '*'); // * should always be the last parameter
if (starpos) while (*starpos == ' ' || *starpos == '*') *starpos-- = '\0'; // nullify '*' and ' '
char *cmd_ptr = current_command;
// Get the command code, which must be G, M, or T
char command_code = *cmd_ptr++;
// Skip spaces to get the numeric part
while (*cmd_ptr == ' ') cmd_ptr++;
uint16_t codenum = 0; // define ahead of goto
// Bail early if there's no code
bool code_is_good = NUMERIC(*cmd_ptr);
if (!code_is_good) goto ExitUnknownCommand;
// Get and skip the code number
do {
codenum = (codenum * 10) + (*cmd_ptr - '0');
cmd_ptr++;
} while (NUMERIC(*cmd_ptr));
// Skip all spaces to get to the first argument, or nul
while (*cmd_ptr == ' ') cmd_ptr++;
// The command's arguments (if any) start here, for sure!
current_command_args = cmd_ptr;
KEEPALIVE_STATE(IN_HANDLER);
// Handle a known G, M, or T
switch (command_code) {
case 'G': switch (codenum) {
// G0, G1
case 0:
case 1:
gcode_G0_G1();
break;
// G2, G3
#if DISABLED(SCARA)
case 2: // G2 - CW ARC
case 3: // G3 - CCW ARC
gcode_G2_G3(codenum == 2);
break;
#endif
// G4 Dwell
case 4:
gcode_G4();
break;
#if ENABLED(FWRETRACT)
case 10: // G10: retract
case 11: // G11: retract_recover
gcode_G10_G11(codenum == 10);
break;
#endif //FWRETRACT
case 28: // G28: Home all axes, one at a time
gcode_G28();
break;
#if ENABLED(AUTO_BED_LEVELING_FEATURE) || ENABLED(MESH_BED_LEVELING)
case 29: // G29 Detailed Z probe, probes the bed at 3 or more points.
gcode_G29();
break;
#endif
#if ENABLED(AUTO_BED_LEVELING_FEATURE)
#if DISABLED(Z_PROBE_SLED)
case 30: // G30 Single Z probe
gcode_G30();
break;
#else // Z_PROBE_SLED
case 31: // G31: dock the sled
case 32: // G32: undock the sled
dock_sled(codenum == 31);
break;
#endif // Z_PROBE_SLED
#endif // AUTO_BED_LEVELING_FEATURE
case 90: // G90
relative_mode = false;
break;
case 91: // G91
relative_mode = true;
break;
case 92: // G92
gcode_G92();
break;
}
break;
case 'M': switch (codenum) {
#if ENABLED(ULTIPANEL)
case 0: // M0 - Unconditional stop - Wait for user button press on LCD
case 1: // M1 - Conditional stop - Wait for user button press on LCD
gcode_M0_M1();
break;
#endif // ULTIPANEL
case 17:
gcode_M17();
break;
#if ENABLED(SDSUPPORT)
case 20: // M20 - list SD card
gcode_M20(); break;
case 21: // M21 - init SD card
gcode_M21(); break;
case 22: //M22 - release SD card
gcode_M22(); break;
case 23: //M23 - Select file
gcode_M23(); break;
case 24: //M24 - Start SD print
gcode_M24(); break;
case 25: //M25 - Pause SD print
gcode_M25(); break;
case 26: //M26 - Set SD index
gcode_M26(); break;
case 27: //M27 - Get SD status
gcode_M27(); break;
case 28: //M28 - Start SD write
gcode_M28(); break;
case 29: //M29 - Stop SD write
gcode_M29(); break;
case 30: //M30 Delete File
gcode_M30(); break;
case 32: //M32 - Select file and start SD print
gcode_M32(); break;
#if ENABLED(LONG_FILENAME_HOST_SUPPORT)
case 33: //M33 - Get the long full path to a file or folder
gcode_M33(); break;
#endif // LONG_FILENAME_HOST_SUPPORT
case 928: //M928 - Start SD write
gcode_M928(); break;
#endif //SDSUPPORT
case 31: //M31 take time since the start of the SD print or an M109 command
gcode_M31();
break;
case 42: //M42 -Change pin status via gcode
gcode_M42();
break;
#if ENABLED(AUTO_BED_LEVELING_FEATURE) && ENABLED(Z_MIN_PROBE_REPEATABILITY_TEST)
case 48: // M48 Z probe repeatability
gcode_M48();
break;
#endif // AUTO_BED_LEVELING_FEATURE && Z_MIN_PROBE_REPEATABILITY_TEST
#if ENABLED(M100_FREE_MEMORY_WATCHER)
case 100:
gcode_M100();
break;
#endif
case 104: // M104
gcode_M104();
break;
case 110: // M110: Set Current Line Number
gcode_M110();
break;
case 111: // M111: Set debug level
gcode_M111();
break;
case 112: // M112: Emergency Stop
gcode_M112();
break;
case 140: // M140: Set bed temp
gcode_M140();
break;
case 105: // M105: Read current temperature
gcode_M105();
KEEPALIVE_STATE(NOT_BUSY);
return; // "ok" already printed
case 109: // M109: Wait for temperature
gcode_M109();
break;
#if HAS_TEMP_BED
case 190: // M190: Wait for bed heater to reach target
gcode_M190();
break;
#endif // HAS_TEMP_BED
#if FAN_COUNT > 0
case 106: // M106: Fan On
gcode_M106();
break;
case 107: // M107: Fan Off
gcode_M107();
break;
#endif // FAN_COUNT > 0
#if ENABLED(BARICUDA)
// PWM for HEATER_1_PIN
#if HAS_HEATER_1
case 126: // M126: valve open
gcode_M126();
break;
case 127: // M127: valve closed
gcode_M127();
break;
#endif // HAS_HEATER_1
// PWM for HEATER_2_PIN
#if HAS_HEATER_2
case 128: // M128: valve open
gcode_M128();
break;
case 129: // M129: valve closed
gcode_M129();
break;
#endif // HAS_HEATER_2
#endif // BARICUDA
#if HAS_POWER_SWITCH
case 80: // M80: Turn on Power Supply
gcode_M80();
break;
#endif // HAS_POWER_SWITCH
case 81: // M81: Turn off Power, including Power Supply, if possible
gcode_M81();
break;
case 82:
gcode_M82();
break;
case 83:
gcode_M83();
break;
case 18: // (for compatibility)
case 84: // M84
gcode_M18_M84();
break;
case 85: // M85
gcode_M85();
break;
case 92: // M92: Set the steps-per-unit for one or more axes
gcode_M92();
break;
case 115: // M115: Report capabilities
gcode_M115();
break;
case 117: // M117: Set LCD message text, if possible
gcode_M117();
break;
case 114: // M114: Report current position
gcode_M114();
break;
case 120: // M120: Enable endstops
gcode_M120();
break;
case 121: // M121: Disable endstops
gcode_M121();
break;
case 119: // M119: Report endstop states
gcode_M119();
break;
#if ENABLED(ULTIPANEL)
case 145: // M145: Set material heatup parameters
gcode_M145();
break;
#endif
#if ENABLED(BLINKM)
case 150: // M150
gcode_M150();
break;
#endif //BLINKM
case 200: // M200 D set filament diameter and set E axis units to cubic millimeters (use S0 to set back to millimeters).
gcode_M200();
break;
case 201: // M201
gcode_M201();
break;
#if 0 // Not used for Sprinter/grbl gen6
case 202: // M202
gcode_M202();
break;
#endif
case 203: // M203 max feedrate mm/sec
gcode_M203();
break;
case 204: // M204 acclereration S normal moves T filmanent only moves
gcode_M204();
break;
case 205: //M205 advanced settings: minimum travel speed S=while printing T=travel only, B=minimum segment time X= maximum xy jerk, Z=maximum Z jerk
gcode_M205();
break;
case 206: // M206 additional homing offset
gcode_M206();
break;
#if ENABLED(DELTA)
case 665: // M665 set delta configurations L R S
gcode_M665();
break;
#endif
#if ENABLED(DELTA) || ENABLED(Z_DUAL_ENDSTOPS)
case 666: // M666 set delta / dual endstop adjustment
gcode_M666();
break;
#endif
#if ENABLED(FWRETRACT)
case 207: //M207 - set retract length S[positive mm] F[feedrate mm/min] Z[additional zlift/hop]
gcode_M207();
break;
case 208: // M208 - set retract recover length S[positive mm surplus to the M207 S*] F[feedrate mm/min]
gcode_M208();
break;
case 209: // M209 - S<1=true/0=false> enable automatic retract detect if the slicer did not support G10/11: every normal extrude-only move will be classified as retract depending on the direction.
gcode_M209();
break;
#endif // FWRETRACT
#if EXTRUDERS > 1
case 218: // M218 - set hotend offset (in mm), T X Y
gcode_M218();
break;
#endif
case 220: // M220 S- set speed factor override percentage
gcode_M220();
break;
case 221: // M221 S- set extrude factor override percentage
gcode_M221();
break;
case 226: // M226 P S- Wait until the specified pin reaches the state required
gcode_M226();
break;
#if HAS_SERVOS
case 280: // M280 - set servo position absolute. P: servo index, S: angle or microseconds
gcode_M280();
break;
#endif // HAS_SERVOS
#if HAS_BUZZER
case 300: // M300 - Play beep tone
gcode_M300();
break;
#endif // HAS_BUZZER
#if ENABLED(PIDTEMP)
case 301: // M301
gcode_M301();
break;
#endif // PIDTEMP
#if ENABLED(PIDTEMPBED)
case 304: // M304
gcode_M304();
break;
#endif // PIDTEMPBED
#if defined(CHDK) || HAS_PHOTOGRAPH
case 240: // M240 Triggers a camera by emulating a Canon RC-1 : http://www.doc-diy.net/photo/rc-1_hacked/
gcode_M240();
break;
#endif // CHDK || PHOTOGRAPH_PIN
#if ENABLED(HAS_LCD_CONTRAST)
case 250: // M250 Set LCD contrast value: C (value 0..63)
gcode_M250();
break;
#endif // HAS_LCD_CONTRAST
#if ENABLED(PREVENT_DANGEROUS_EXTRUDE)
case 302: // allow cold extrudes, or set the minimum extrude temperature
gcode_M302();
break;
#endif // PREVENT_DANGEROUS_EXTRUDE
case 303: // M303 PID autotune
gcode_M303();
break;
#if ENABLED(SCARA)
case 360: // M360 SCARA Theta pos1
if (gcode_M360()) return;
break;
case 361: // M361 SCARA Theta pos2
if (gcode_M361()) return;
break;
case 362: // M362 SCARA Psi pos1
if (gcode_M362()) return;
break;
case 363: // M363 SCARA Psi pos2
if (gcode_M363()) return;
break;
case 364: // M364 SCARA Psi pos3 (90 deg to Theta)
if (gcode_M364()) return;
break;
case 365: // M365 Set SCARA scaling for X Y Z
gcode_M365();
break;
#endif // SCARA
case 400: // M400 finish all moves
gcode_M400();
break;
#if ENABLED(AUTO_BED_LEVELING_FEATURE) && (HAS_SERVO_ENDSTOPS || ENABLED(Z_PROBE_ALLEN_KEY)) && DISABLED(Z_PROBE_SLED)
case 401:
gcode_M401();
break;
case 402:
gcode_M402();
break;
#endif // AUTO_BED_LEVELING_FEATURE && (HAS_SERVO_ENDSTOPS || Z_PROBE_ALLEN_KEY) && !Z_PROBE_SLED
#if ENABLED(FILAMENT_WIDTH_SENSOR)
case 404: //M404 Enter the nominal filament width (3mm, 1.75mm ) N<3.0> or display nominal filament width
gcode_M404();
break;
case 405: //M405 Turn on filament sensor for control
gcode_M405();
break;
case 406: //M406 Turn off filament sensor for control
gcode_M406();
break;
case 407: //M407 Display measured filament diameter
gcode_M407();
break;
#endif // ENABLED(FILAMENT_WIDTH_SENSOR)
case 410: // M410 quickstop - Abort all the planned moves.
gcode_M410();
break;
#if ENABLED(MESH_BED_LEVELING)
case 420: // M420 Enable/Disable Mesh Bed Leveling
gcode_M420();
break;
case 421: // M421 Set a Mesh Bed Leveling Z coordinate
gcode_M421();
break;
#endif
case 428: // M428 Apply current_position to home_offset
gcode_M428();
break;
case 500: // M500 Store settings in EEPROM
gcode_M500();
break;
case 501: // M501 Read settings from EEPROM
gcode_M501();
break;
case 502: // M502 Revert to default settings
gcode_M502();
break;
case 503: // M503 print settings currently in memory
gcode_M503();
break;
#if ENABLED(ABORT_ON_ENDSTOP_HIT_FEATURE_ENABLED)
case 540:
gcode_M540();
break;
#endif
#ifdef CUSTOM_M_CODE_SET_Z_PROBE_OFFSET
case CUSTOM_M_CODE_SET_Z_PROBE_OFFSET:
gcode_SET_Z_PROBE_OFFSET();
break;
#endif // CUSTOM_M_CODE_SET_Z_PROBE_OFFSET
#if ENABLED(FILAMENTCHANGEENABLE)
case 600: //Pause for filament change X[pos] Y[pos] Z[relative lift] E[initial retract] L[later retract distance for removal]
gcode_M600();
break;
#endif // FILAMENTCHANGEENABLE
#if ENABLED(DUAL_X_CARRIAGE)
case 605:
gcode_M605();
break;
#endif // DUAL_X_CARRIAGE
case 907: // M907 Set digital trimpot motor current using axis codes.
gcode_M907();
break;
#if HAS_DIGIPOTSS || ENABLED(DAC_STEPPER_CURRENT)
case 908: // M908 Control digital trimpot directly.
gcode_M908();
break;
#if ENABLED(DAC_STEPPER_CURRENT) // As with Printrbot RevF
case 909: // M909 Print digipot/DAC current value
gcode_M909();
break;
case 910: // M910 Commit digipot/DAC value to external EEPROM
gcode_M910();
break;
#endif
#endif // HAS_DIGIPOTSS || DAC_STEPPER_CURRENT
#if HAS_MICROSTEPS
case 350: // M350 Set microstepping mode. Warning: Steps per unit remains unchanged. S code sets stepping mode for all drivers.
gcode_M350();
break;
case 351: // M351 Toggle MS1 MS2 pins directly, S# determines MS1 or MS2, X# sets the pin high/low.
gcode_M351();
break;
#endif // HAS_MICROSTEPS
case 999: // M999: Restart after being Stopped
gcode_M999();
break;
}
break;
case 'T':
gcode_T(codenum);
break;
default: code_is_good = false;
}
KEEPALIVE_STATE(NOT_BUSY);
ExitUnknownCommand:
// Still unknown command? Throw an error
if (!code_is_good) unknown_command_error();
ok_to_send();
}
void FlushSerialRequestResend() {
//char command_queue[cmd_queue_index_r][100]="Resend:";
MYSERIAL.flush();
SERIAL_PROTOCOLPGM(MSG_RESEND);
SERIAL_PROTOCOLLN(gcode_LastN + 1);
ok_to_send();
}
void ok_to_send() {
refresh_cmd_timeout();
if (!send_ok[cmd_queue_index_r]) return;
SERIAL_PROTOCOLPGM(MSG_OK);
#if ENABLED(ADVANCED_OK)
char* p = command_queue[cmd_queue_index_r];
if (*p == 'N') {
SERIAL_PROTOCOL(' ');
SERIAL_ECHO(*p++);
while (NUMERIC_SIGNED(*p))
SERIAL_ECHO(*p++);
}
SERIAL_PROTOCOLPGM(" P"); SERIAL_PROTOCOL(int(BLOCK_BUFFER_SIZE - movesplanned() - 1));
SERIAL_PROTOCOLPGM(" B"); SERIAL_PROTOCOL(BUFSIZE - commands_in_queue);
#endif
SERIAL_EOL;
}
void clamp_to_software_endstops(float target[3]) {
if (min_software_endstops) {
NOLESS(target[X_AXIS], min_pos[X_AXIS]);
NOLESS(target[Y_AXIS], min_pos[Y_AXIS]);
float negative_z_offset = 0;
#if ENABLED(AUTO_BED_LEVELING_FEATURE)
if (zprobe_zoffset < 0) negative_z_offset += zprobe_zoffset;
if (home_offset[Z_AXIS] < 0) {
#if ENABLED(DEBUG_LEVELING_FEATURE)
if (DEBUGGING(LEVELING)) {
SERIAL_ECHOPAIR("> clamp_to_software_endstops > Add home_offset[Z_AXIS]:", home_offset[Z_AXIS]);
SERIAL_EOL;
}
#endif
negative_z_offset += home_offset[Z_AXIS];
}
#endif
NOLESS(target[Z_AXIS], min_pos[Z_AXIS] + negative_z_offset);
}
if (max_software_endstops) {
NOMORE(target[X_AXIS], max_pos[X_AXIS]);
NOMORE(target[Y_AXIS], max_pos[Y_AXIS]);
NOMORE(target[Z_AXIS], max_pos[Z_AXIS]);
}
}
#if ENABLED(DELTA)
void recalc_delta_settings(float radius, float diagonal_rod) {
delta_tower1_x = -SIN_60 * (radius + DELTA_RADIUS_TRIM_TOWER_1); // front left tower
delta_tower1_y = -COS_60 * (radius + DELTA_RADIUS_TRIM_TOWER_1);
delta_tower2_x = SIN_60 * (radius + DELTA_RADIUS_TRIM_TOWER_2); // front right tower
delta_tower2_y = -COS_60 * (radius + DELTA_RADIUS_TRIM_TOWER_2);
delta_tower3_x = 0.0; // back middle tower
delta_tower3_y = (radius + DELTA_RADIUS_TRIM_TOWER_3);
delta_diagonal_rod_2_tower_1 = sq(diagonal_rod + delta_diagonal_rod_trim_tower_1);
delta_diagonal_rod_2_tower_2 = sq(diagonal_rod + delta_diagonal_rod_trim_tower_2);
delta_diagonal_rod_2_tower_3 = sq(diagonal_rod + delta_diagonal_rod_trim_tower_3);
}
void calculate_delta(float cartesian[3]) {
delta[TOWER_1] = sqrt(delta_diagonal_rod_2_tower_1
- sq(delta_tower1_x - cartesian[X_AXIS])
- sq(delta_tower1_y - cartesian[Y_AXIS])
) + cartesian[Z_AXIS];
delta[TOWER_2] = sqrt(delta_diagonal_rod_2_tower_2
- sq(delta_tower2_x - cartesian[X_AXIS])
- sq(delta_tower2_y - cartesian[Y_AXIS])
) + cartesian[Z_AXIS];
delta[TOWER_3] = sqrt(delta_diagonal_rod_2_tower_3
- sq(delta_tower3_x - cartesian[X_AXIS])
- sq(delta_tower3_y - cartesian[Y_AXIS])
) + cartesian[Z_AXIS];
/**
SERIAL_ECHOPGM("cartesian x="); SERIAL_ECHO(cartesian[X_AXIS]);
SERIAL_ECHOPGM(" y="); SERIAL_ECHO(cartesian[Y_AXIS]);
SERIAL_ECHOPGM(" z="); SERIAL_ECHOLN(cartesian[Z_AXIS]);
SERIAL_ECHOPGM("delta a="); SERIAL_ECHO(delta[TOWER_1]);
SERIAL_ECHOPGM(" b="); SERIAL_ECHO(delta[TOWER_2]);
SERIAL_ECHOPGM(" c="); SERIAL_ECHOLN(delta[TOWER_3]);
*/
}
#if ENABLED(AUTO_BED_LEVELING_FEATURE)
// Adjust print surface height by linear interpolation over the bed_level array.
void adjust_delta(float cartesian[3]) {
if (delta_grid_spacing[0] == 0 || delta_grid_spacing[1] == 0) return; // G29 not done!
int half = (AUTO_BED_LEVELING_GRID_POINTS - 1) / 2;
float h1 = 0.001 - half, h2 = half - 0.001,
grid_x = max(h1, min(h2, cartesian[X_AXIS] / delta_grid_spacing[0])),
grid_y = max(h1, min(h2, cartesian[Y_AXIS] / delta_grid_spacing[1]));
int floor_x = floor(grid_x), floor_y = floor(grid_y);
float ratio_x = grid_x - floor_x, ratio_y = grid_y - floor_y,
z1 = bed_level[floor_x + half][floor_y + half],
z2 = bed_level[floor_x + half][floor_y + half + 1],
z3 = bed_level[floor_x + half + 1][floor_y + half],
z4 = bed_level[floor_x + half + 1][floor_y + half + 1],
left = (1 - ratio_y) * z1 + ratio_y * z2,
right = (1 - ratio_y) * z3 + ratio_y * z4,
offset = (1 - ratio_x) * left + ratio_x * right;
delta[X_AXIS] += offset;
delta[Y_AXIS] += offset;
delta[Z_AXIS] += offset;
/**
SERIAL_ECHOPGM("grid_x="); SERIAL_ECHO(grid_x);
SERIAL_ECHOPGM(" grid_y="); SERIAL_ECHO(grid_y);
SERIAL_ECHOPGM(" floor_x="); SERIAL_ECHO(floor_x);
SERIAL_ECHOPGM(" floor_y="); SERIAL_ECHO(floor_y);
SERIAL_ECHOPGM(" ratio_x="); SERIAL_ECHO(ratio_x);
SERIAL_ECHOPGM(" ratio_y="); SERIAL_ECHO(ratio_y);
SERIAL_ECHOPGM(" z1="); SERIAL_ECHO(z1);
SERIAL_ECHOPGM(" z2="); SERIAL_ECHO(z2);
SERIAL_ECHOPGM(" z3="); SERIAL_ECHO(z3);
SERIAL_ECHOPGM(" z4="); SERIAL_ECHO(z4);
SERIAL_ECHOPGM(" left="); SERIAL_ECHO(left);
SERIAL_ECHOPGM(" right="); SERIAL_ECHO(right);
SERIAL_ECHOPGM(" offset="); SERIAL_ECHOLN(offset);
*/
}
#endif // AUTO_BED_LEVELING_FEATURE
#endif // DELTA
#if ENABLED(MESH_BED_LEVELING)
// This function is used to split lines on mesh borders so each segment is only part of one mesh area
void mesh_plan_buffer_line(float x, float y, float z, const float e, float feed_rate, const uint8_t& extruder, uint8_t x_splits = 0xff, uint8_t y_splits = 0xff) {
if (!mbl.active) {
plan_buffer_line(x, y, z, e, feed_rate, extruder);
set_current_to_destination();
return;
}
int pix = mbl.select_x_index(current_position[X_AXIS]);
int piy = mbl.select_y_index(current_position[Y_AXIS]);
int ix = mbl.select_x_index(x);
int iy = mbl.select_y_index(y);
pix = min(pix, MESH_NUM_X_POINTS - 2);
piy = min(piy, MESH_NUM_Y_POINTS - 2);
ix = min(ix, MESH_NUM_X_POINTS - 2);
iy = min(iy, MESH_NUM_Y_POINTS - 2);
if (pix == ix && piy == iy) {
// Start and end on same mesh square
plan_buffer_line(x, y, z, e, feed_rate, extruder);
set_current_to_destination();
return;
}
float nx, ny, nz, ne, normalized_dist;
if (ix > pix && TEST(x_splits, ix)) {
nx = mbl.get_x(ix);
normalized_dist = (nx - current_position[X_AXIS]) / (x - current_position[X_AXIS]);
ny = current_position[Y_AXIS] + (y - current_position[Y_AXIS]) * normalized_dist;
nz = current_position[Z_AXIS] + (z - current_position[Z_AXIS]) * normalized_dist;
ne = current_position[E_AXIS] + (e - current_position[E_AXIS]) * normalized_dist;
CBI(x_splits, ix);
}
else if (ix < pix && TEST(x_splits, pix)) {
nx = mbl.get_x(pix);
normalized_dist = (nx - current_position[X_AXIS]) / (x - current_position[X_AXIS]);
ny = current_position[Y_AXIS] + (y - current_position[Y_AXIS]) * normalized_dist;
nz = current_position[Z_AXIS] + (z - current_position[Z_AXIS]) * normalized_dist;
ne = current_position[E_AXIS] + (e - current_position[E_AXIS]) * normalized_dist;
CBI(x_splits, pix);
}
else if (iy > piy && TEST(y_splits, iy)) {
ny = mbl.get_y(iy);
normalized_dist = (ny - current_position[Y_AXIS]) / (y - current_position[Y_AXIS]);
nx = current_position[X_AXIS] + (x - current_position[X_AXIS]) * normalized_dist;
nz = current_position[Z_AXIS] + (z - current_position[Z_AXIS]) * normalized_dist;
ne = current_position[E_AXIS] + (e - current_position[E_AXIS]) * normalized_dist;
CBI(y_splits, iy);
}
else if (iy < piy && TEST(y_splits, piy)) {
ny = mbl.get_y(piy);
normalized_dist = (ny - current_position[Y_AXIS]) / (y - current_position[Y_AXIS]);
nx = current_position[X_AXIS] + (x - current_position[X_AXIS]) * normalized_dist;
nz = current_position[Z_AXIS] + (z - current_position[Z_AXIS]) * normalized_dist;
ne = current_position[E_AXIS] + (e - current_position[E_AXIS]) * normalized_dist;
CBI(y_splits, piy);
}
else {
// Already split on a border
plan_buffer_line(x, y, z, e, feed_rate, extruder);
set_current_to_destination();
return;
}
// Do the split and look for more borders
destination[X_AXIS] = nx;
destination[Y_AXIS] = ny;
destination[Z_AXIS] = nz;
destination[E_AXIS] = ne;
mesh_plan_buffer_line(nx, ny, nz, ne, feed_rate, extruder, x_splits, y_splits);
destination[X_AXIS] = x;
destination[Y_AXIS] = y;
destination[Z_AXIS] = z;
destination[E_AXIS] = e;
mesh_plan_buffer_line(x, y, z, e, feed_rate, extruder, x_splits, y_splits);
}
#endif // MESH_BED_LEVELING
#if ENABLED(PREVENT_DANGEROUS_EXTRUDE)
inline void prevent_dangerous_extrude(float& curr_e, float& dest_e) {
if (DEBUGGING(DRYRUN)) return;
float de = dest_e - curr_e;
if (de) {
if (degHotend(active_extruder) < extrude_min_temp) {
curr_e = dest_e; // Behave as if the move really took place, but ignore E part
SERIAL_ECHO_START;
SERIAL_ECHOLNPGM(MSG_ERR_COLD_EXTRUDE_STOP);
}
#if ENABLED(PREVENT_LENGTHY_EXTRUDE)
if (labs(de) > EXTRUDE_MAXLENGTH) {
curr_e = dest_e; // Behave as if the move really took place, but ignore E part
SERIAL_ECHO_START;
SERIAL_ECHOLNPGM(MSG_ERR_LONG_EXTRUDE_STOP);
}
#endif
}
}
#endif // PREVENT_DANGEROUS_EXTRUDE
#if ENABLED(DELTA) || ENABLED(SCARA)
inline bool prepare_move_delta(float target[NUM_AXIS]) {
float difference[NUM_AXIS];
for (int8_t i = 0; i < NUM_AXIS; i++) difference[i] = target[i] - current_position[i];
float cartesian_mm = sqrt(sq(difference[X_AXIS]) + sq(difference[Y_AXIS]) + sq(difference[Z_AXIS]));
if (cartesian_mm < 0.000001) cartesian_mm = abs(difference[E_AXIS]);
if (cartesian_mm < 0.000001) return false;
float seconds = 6000 * cartesian_mm / feedrate / feedrate_multiplier;
int steps = max(1, int(delta_segments_per_second * seconds));
// SERIAL_ECHOPGM("mm="); SERIAL_ECHO(cartesian_mm);
// SERIAL_ECHOPGM(" seconds="); SERIAL_ECHO(seconds);
// SERIAL_ECHOPGM(" steps="); SERIAL_ECHOLN(steps);
for (int s = 1; s <= steps; s++) {
float fraction = float(s) / float(steps);
for (int8_t i = 0; i < NUM_AXIS; i++)
target[i] = current_position[i] + difference[i] * fraction;
calculate_delta(target);
#if ENABLED(AUTO_BED_LEVELING_FEATURE)
adjust_delta(target);
#endif
//SERIAL_ECHOPGM("target[X_AXIS]="); SERIAL_ECHOLN(target[X_AXIS]);
//SERIAL_ECHOPGM("target[Y_AXIS]="); SERIAL_ECHOLN(target[Y_AXIS]);
//SERIAL_ECHOPGM("target[Z_AXIS]="); SERIAL_ECHOLN(target[Z_AXIS]);
//SERIAL_ECHOPGM("delta[X_AXIS]="); SERIAL_ECHOLN(delta[X_AXIS]);
//SERIAL_ECHOPGM("delta[Y_AXIS]="); SERIAL_ECHOLN(delta[Y_AXIS]);
//SERIAL_ECHOPGM("delta[Z_AXIS]="); SERIAL_ECHOLN(delta[Z_AXIS]);
plan_buffer_line(delta[X_AXIS], delta[Y_AXIS], delta[Z_AXIS], target[E_AXIS], feedrate / 60 * feedrate_multiplier / 100.0, active_extruder);
}
return true;
}
#endif // DELTA || SCARA
#if ENABLED(SCARA)
inline bool prepare_move_scara(float target[NUM_AXIS]) { return prepare_move_delta(target); }
#endif
#if ENABLED(DUAL_X_CARRIAGE)
inline bool prepare_move_dual_x_carriage() {
if (active_extruder_parked) {
if (dual_x_carriage_mode == DXC_DUPLICATION_MODE && active_extruder == 0) {
// move duplicate extruder into correct duplication position.
plan_set_position(inactive_extruder_x_pos, current_position[Y_AXIS], current_position[Z_AXIS], current_position[E_AXIS]);
plan_buffer_line(current_position[X_AXIS] + duplicate_extruder_x_offset,
current_position[Y_AXIS], current_position[Z_AXIS], current_position[E_AXIS], max_feedrate[X_AXIS], 1);
sync_plan_position();
st_synchronize();
extruder_duplication_enabled = true;
active_extruder_parked = false;
}
else if (dual_x_carriage_mode == DXC_AUTO_PARK_MODE) { // handle unparking of head
if (current_position[E_AXIS] == destination[E_AXIS]) {
// This is a travel move (with no extrusion)
// Skip it, but keep track of the current position
// (so it can be used as the start of the next non-travel move)
if (delayed_move_time != 0xFFFFFFFFUL) {
set_current_to_destination();
NOLESS(raised_parked_position[Z_AXIS], destination[Z_AXIS]);
delayed_move_time = millis();
return false;
}
}
delayed_move_time = 0;
// unpark extruder: 1) raise, 2) move into starting XY position, 3) lower
plan_buffer_line(raised_parked_position[X_AXIS], raised_parked_position[Y_AXIS], raised_parked_position[Z_AXIS], current_position[E_AXIS], max_feedrate[Z_AXIS], active_extruder);
plan_buffer_line(current_position[X_AXIS], current_position[Y_AXIS], raised_parked_position[Z_AXIS], current_position[E_AXIS], min(max_feedrate[X_AXIS], max_feedrate[Y_AXIS]), active_extruder);
plan_buffer_line(current_position[X_AXIS], current_position[Y_AXIS], current_position[Z_AXIS], current_position[E_AXIS], max_feedrate[Z_AXIS], active_extruder);
active_extruder_parked = false;
}
}
return true;
}
#endif // DUAL_X_CARRIAGE
#if DISABLED(DELTA) && DISABLED(SCARA)
inline bool prepare_move_cartesian() {
// Do not use feedrate_multiplier for E or Z only moves
if (current_position[X_AXIS] == destination[X_AXIS] && current_position[Y_AXIS] == destination[Y_AXIS]) {
line_to_destination();
}
else {
#if ENABLED(MESH_BED_LEVELING)
mesh_plan_buffer_line(destination[X_AXIS], destination[Y_AXIS], destination[Z_AXIS], destination[E_AXIS], (feedrate / 60) * (feedrate_multiplier / 100.0), active_extruder);
return false;
#else
line_to_destination(feedrate * feedrate_multiplier / 100.0);
#endif
}
return true;
}
#endif // !DELTA && !SCARA
/**
* Prepare a single move and get ready for the next one
*
* (This may call plan_buffer_line several times to put
* smaller moves into the planner for DELTA or SCARA.)
*/
void prepare_move() {
clamp_to_software_endstops(destination);
refresh_cmd_timeout();
#if ENABLED(PREVENT_DANGEROUS_EXTRUDE)
prevent_dangerous_extrude(current_position[E_AXIS], destination[E_AXIS]);
#endif
#if ENABLED(SCARA)
if (!prepare_move_scara(destination)) return;
#elif ENABLED(DELTA)
if (!prepare_move_delta(destination)) return;
#endif
#if ENABLED(DUAL_X_CARRIAGE)
if (!prepare_move_dual_x_carriage()) return;
#endif
#if DISABLED(DELTA) && DISABLED(SCARA)
if (!prepare_move_cartesian()) return;
#endif
set_current_to_destination();
}
/**
* Plan an arc in 2 dimensions
*
* The arc is approximated by generating many small linear segments.
* The length of each segment is configured in MM_PER_ARC_SEGMENT (Default 1mm)
* Arcs should only be made relatively large (over 5mm), as larger arcs with
* larger segments will tend to be more efficient. Your slicer should have
* options for G2/G3 arc generation. In future these options may be GCode tunable.
*/
void plan_arc(
float target[NUM_AXIS], // Destination position
float* offset, // Center of rotation relative to current_position
uint8_t clockwise // Clockwise?
) {
float radius = hypot(offset[X_AXIS], offset[Y_AXIS]),
center_axis0 = current_position[X_AXIS] + offset[X_AXIS],
center_axis1 = current_position[Y_AXIS] + offset[Y_AXIS],
linear_travel = target[Z_AXIS] - current_position[Z_AXIS],
extruder_travel = target[E_AXIS] - current_position[E_AXIS],
r_axis0 = -offset[X_AXIS], // Radius vector from center to current location
r_axis1 = -offset[Y_AXIS],
rt_axis0 = target[X_AXIS] - center_axis0,
rt_axis1 = target[Y_AXIS] - center_axis1;
// CCW angle of rotation between position and target from the 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 += RADIANS(360);
if (clockwise) angular_travel -= RADIANS(360);
// Make a circle if the angular rotation is 0
if (current_position[X_AXIS] == target[X_AXIS] && current_position[Y_AXIS] == target[Y_AXIS] && angular_travel == 0)
angular_travel += RADIANS(360);
float mm_of_travel = hypot(angular_travel * radius, fabs(linear_travel));
if (mm_of_travel < 0.001) return;
uint16_t segments = floor(mm_of_travel / (MM_PER_ARC_SEGMENT));
if (segments == 0) segments = 1;
float theta_per_segment = angular_travel / segments;
float linear_per_segment = linear_travel / segments;
float extruder_per_segment = extruder_travel / segments;
/**
* Vector rotation by transformation matrix: r is the original vector, r_T is the rotated vector,
* and phi is the angle of rotation. Based on the solution approach by Jens Geisler.
* r_T = [cos(phi) -sin(phi);
* sin(phi) cos(phi] * r ;
*
* For arc generation, the center of the circle is the axis of rotation and the radius vector is
* defined from the circle center to the initial position. Each line segment is formed by successive
* vector rotations. This requires only two cos() and sin() computations to form the rotation
* matrix for the duration of the entire arc. Error may accumulate from numerical round-off, since
* all double numbers are single precision on the Arduino. (True double precision will not have
* round off issues for CNC applications.) Single precision error can accumulate to be greater than
* tool precision in some cases. Therefore, arc path correction is implemented.
*
* Small angle approximation may be used to reduce computation overhead further. This approximation
* holds for everything, but very small circles and large MM_PER_ARC_SEGMENT values. In other words,
* theta_per_segment would need to be greater than 0.1 rad and N_ARC_CORRECTION would need to be large
* to cause an appreciable drift error. N_ARC_CORRECTION~=25 is more than small enough to correct for
* numerical drift error. N_ARC_CORRECTION may be on the order a hundred(s) before error becomes an
* issue for CNC machines with the single precision Arduino calculations.
*
* This approximation also allows plan_arc to immediately insert a line segment into the planner
* without the initial overhead of computing cos() or sin(). By the time the arc needs to be applied
* a correction, the planner should have caught up to the lag caused by the initial plan_arc overhead.
* This is important when there are successive arc motions.
*/
// Vector rotation matrix values
float cos_T = 1 - 0.5 * theta_per_segment * theta_per_segment; // Small angle approximation
float sin_T = theta_per_segment;
float arc_target[NUM_AXIS];
float sin_Ti;
float cos_Ti;
float r_axisi;
uint16_t i;
int8_t count = 0;
// Initialize the linear axis
arc_target[Z_AXIS] = current_position[Z_AXIS];
// Initialize the extruder axis
arc_target[E_AXIS] = current_position[E_AXIS];
float feed_rate = feedrate * feedrate_multiplier / 60 / 100.0;
for (i = 1; i < segments; i++) { // Increment (segments-1)
if (count < N_ARC_CORRECTION) {
// Apply vector rotation matrix to previous r_axis0 / 1
r_axisi = r_axis0 * sin_T + r_axis1 * cos_T;
r_axis0 = r_axis0 * cos_T - r_axis1 * sin_T;
r_axis1 = r_axisi;
count++;
}
else {
// Arc correction to radius vector. Computed only every N_ARC_CORRECTION increments.
// Compute exact location by applying transformation matrix from initial radius vector(=-offset).
cos_Ti = cos(i * theta_per_segment);
sin_Ti = sin(i * theta_per_segment);
r_axis0 = -offset[X_AXIS] * cos_Ti + offset[Y_AXIS] * sin_Ti;
r_axis1 = -offset[X_AXIS] * sin_Ti - offset[Y_AXIS] * cos_Ti;
count = 0;
}
// Update arc_target location
arc_target[X_AXIS] = center_axis0 + r_axis0;
arc_target[Y_AXIS] = center_axis1 + r_axis1;
arc_target[Z_AXIS] += linear_per_segment;
arc_target[E_AXIS] += extruder_per_segment;
clamp_to_software_endstops(arc_target);
#if ENABLED(DELTA) || ENABLED(SCARA)
calculate_delta(arc_target);
#if ENABLED(AUTO_BED_LEVELING_FEATURE)
adjust_delta(arc_target);
#endif
plan_buffer_line(delta[X_AXIS], delta[Y_AXIS], delta[Z_AXIS], arc_target[E_AXIS], feed_rate, active_extruder);
#else
plan_buffer_line(arc_target[X_AXIS], arc_target[Y_AXIS], arc_target[Z_AXIS], arc_target[E_AXIS], feed_rate, active_extruder);
#endif
}
// Ensure last segment arrives at target location.
#if ENABLED(DELTA) || ENABLED(SCARA)
calculate_delta(target);
#if ENABLED(AUTO_BED_LEVELING_FEATURE)
adjust_delta(target);
#endif
plan_buffer_line(delta[X_AXIS], delta[Y_AXIS], delta[Z_AXIS], target[E_AXIS], feed_rate, active_extruder);
#else
plan_buffer_line(target[X_AXIS], target[Y_AXIS], target[Z_AXIS], target[E_AXIS], feed_rate, active_extruder);
#endif
// As far as the parser is concerned, the position is now == target. In reality the
// motion control system might still be processing the action and the real tool position
// in any intermediate location.
set_current_to_destination();
}
#if HAS_CONTROLLERFAN
void controllerFan() {
static millis_t lastMotorOn = 0; // Last time a motor was turned on
static millis_t nextMotorCheck = 0; // Last time the state was checked
millis_t ms = millis();
if (ms >= nextMotorCheck) {
nextMotorCheck = ms + 2500; // Not a time critical function, so only check every 2.5s
if (X_ENABLE_READ == X_ENABLE_ON || Y_ENABLE_READ == Y_ENABLE_ON || Z_ENABLE_READ == Z_ENABLE_ON || soft_pwm_bed > 0
|| E0_ENABLE_READ == E_ENABLE_ON // If any of the drivers are enabled...
#if EXTRUDERS > 1
|| E1_ENABLE_READ == E_ENABLE_ON
#if HAS_X2_ENABLE
|| X2_ENABLE_READ == X_ENABLE_ON
#endif
#if EXTRUDERS > 2
|| E2_ENABLE_READ == E_ENABLE_ON
#if EXTRUDERS > 3
|| E3_ENABLE_READ == E_ENABLE_ON
#endif
#endif
#endif
) {
lastMotorOn = ms; //... set time to NOW so the fan will turn on
}
// Fan off if no steppers have been enabled for CONTROLLERFAN_SECS seconds
uint8_t speed = (lastMotorOn == 0 || ms >= lastMotorOn + (CONTROLLERFAN_SECS) * 1000UL) ? 0 : CONTROLLERFAN_SPEED;
// allows digital or PWM fan output to be used (see M42 handling)
digitalWrite(CONTROLLERFAN_PIN, speed);
analogWrite(CONTROLLERFAN_PIN, speed);
}
}
#endif // HAS_CONTROLLERFAN
#if ENABLED(SCARA)
void calculate_SCARA_forward_Transform(float f_scara[3]) {
// Perform forward kinematics, and place results in delta[3]
// The maths and first version has been done by QHARLEY . Integrated into masterbranch 06/2014 and slightly restructured by Joachim Cerny in June 2014
float x_sin, x_cos, y_sin, y_cos;
//SERIAL_ECHOPGM("f_delta x="); SERIAL_ECHO(f_scara[X_AXIS]);
//SERIAL_ECHOPGM(" y="); SERIAL_ECHO(f_scara[Y_AXIS]);
x_sin = sin(f_scara[X_AXIS] / SCARA_RAD2DEG) * Linkage_1;
x_cos = cos(f_scara[X_AXIS] / SCARA_RAD2DEG) * Linkage_1;
y_sin = sin(f_scara[Y_AXIS] / SCARA_RAD2DEG) * Linkage_2;
y_cos = cos(f_scara[Y_AXIS] / SCARA_RAD2DEG) * Linkage_2;
//SERIAL_ECHOPGM(" x_sin="); SERIAL_ECHO(x_sin);
//SERIAL_ECHOPGM(" x_cos="); SERIAL_ECHO(x_cos);
//SERIAL_ECHOPGM(" y_sin="); SERIAL_ECHO(y_sin);
//SERIAL_ECHOPGM(" y_cos="); SERIAL_ECHOLN(y_cos);
delta[X_AXIS] = x_cos + y_cos + SCARA_offset_x; //theta
delta[Y_AXIS] = x_sin + y_sin + SCARA_offset_y; //theta+phi
//SERIAL_ECHOPGM(" delta[X_AXIS]="); SERIAL_ECHO(delta[X_AXIS]);
//SERIAL_ECHOPGM(" delta[Y_AXIS]="); SERIAL_ECHOLN(delta[Y_AXIS]);
}
void calculate_delta(float cartesian[3]) {
//reverse kinematics.
// Perform reversed kinematics, and place results in delta[3]
// The maths and first version has been done by QHARLEY . Integrated into masterbranch 06/2014 and slightly restructured by Joachim Cerny in June 2014
float SCARA_pos[2];
static float SCARA_C2, SCARA_S2, SCARA_K1, SCARA_K2, SCARA_theta, SCARA_psi;
SCARA_pos[X_AXIS] = cartesian[X_AXIS] * axis_scaling[X_AXIS] - SCARA_offset_x; //Translate SCARA to standard X Y
SCARA_pos[Y_AXIS] = cartesian[Y_AXIS] * axis_scaling[Y_AXIS] - SCARA_offset_y; // With scaling factor.
#if (Linkage_1 == Linkage_2)
SCARA_C2 = ((sq(SCARA_pos[X_AXIS]) + sq(SCARA_pos[Y_AXIS])) / (2 * (float)L1_2)) - 1;
#else
SCARA_C2 = (sq(SCARA_pos[X_AXIS]) + sq(SCARA_pos[Y_AXIS]) - (float)L1_2 - (float)L2_2) / 45000;
#endif
SCARA_S2 = sqrt(1 - sq(SCARA_C2));
SCARA_K1 = Linkage_1 + Linkage_2 * SCARA_C2;
SCARA_K2 = Linkage_2 * SCARA_S2;
SCARA_theta = (atan2(SCARA_pos[X_AXIS], SCARA_pos[Y_AXIS]) - atan2(SCARA_K1, SCARA_K2)) * -1;
SCARA_psi = atan2(SCARA_S2, SCARA_C2);
delta[X_AXIS] = SCARA_theta * SCARA_RAD2DEG; // Multiply by 180/Pi - theta is support arm angle
delta[Y_AXIS] = (SCARA_theta + SCARA_psi) * SCARA_RAD2DEG; // - equal to sub arm angle (inverted motor)
delta[Z_AXIS] = cartesian[Z_AXIS];
/**
SERIAL_ECHOPGM("cartesian x="); SERIAL_ECHO(cartesian[X_AXIS]);
SERIAL_ECHOPGM(" y="); SERIAL_ECHO(cartesian[Y_AXIS]);
SERIAL_ECHOPGM(" z="); SERIAL_ECHOLN(cartesian[Z_AXIS]);
SERIAL_ECHOPGM("scara x="); SERIAL_ECHO(SCARA_pos[X_AXIS]);
SERIAL_ECHOPGM(" y="); SERIAL_ECHOLN(SCARA_pos[Y_AXIS]);
SERIAL_ECHOPGM("delta x="); SERIAL_ECHO(delta[X_AXIS]);
SERIAL_ECHOPGM(" y="); SERIAL_ECHO(delta[Y_AXIS]);
SERIAL_ECHOPGM(" z="); SERIAL_ECHOLN(delta[Z_AXIS]);
SERIAL_ECHOPGM("C2="); SERIAL_ECHO(SCARA_C2);
SERIAL_ECHOPGM(" S2="); SERIAL_ECHO(SCARA_S2);
SERIAL_ECHOPGM(" Theta="); SERIAL_ECHO(SCARA_theta);
SERIAL_ECHOPGM(" Psi="); SERIAL_ECHOLN(SCARA_psi);
SERIAL_EOL;
*/
}
#endif // SCARA
#if ENABLED(TEMP_STAT_LEDS)
static bool red_led = false;
static millis_t next_status_led_update_ms = 0;
void handle_status_leds(void) {
float max_temp = 0.0;
if (millis() > next_status_led_update_ms) {
next_status_led_update_ms += 500; // Update every 0.5s
for (int8_t cur_extruder = 0; cur_extruder < EXTRUDERS; ++cur_extruder)
max_temp = max(max(max_temp, degHotend(cur_extruder)), degTargetHotend(cur_extruder));
#if HAS_TEMP_BED
max_temp = max(max(max_temp, degTargetBed()), degBed());
#endif
bool new_led = (max_temp > 55.0) ? true : (max_temp < 54.0) ? false : red_led;
if (new_led != red_led) {
red_led = new_led;
digitalWrite(STAT_LED_RED, new_led ? HIGH : LOW);
digitalWrite(STAT_LED_BLUE, new_led ? LOW : HIGH);
}
}
}
#endif
void enable_all_steppers() {
enable_x();
enable_y();
enable_z();
enable_e0();
enable_e1();
enable_e2();
enable_e3();
}
void disable_all_steppers() {
disable_x();
disable_y();
disable_z();
disable_e0();
disable_e1();
disable_e2();
disable_e3();
}
/**
* Standard idle routine keeps the machine alive
*/
void idle(
#if ENABLED(FILAMENTCHANGEENABLE)
bool no_stepper_sleep/*=false*/
#endif
) {
manage_heater();
manage_inactivity(
#if ENABLED(FILAMENTCHANGEENABLE)
no_stepper_sleep
#endif
);
host_keepalive();
lcd_update();
}
/**
* Manage several activities:
* - Check for Filament Runout
* - Keep the command buffer full
* - Check for maximum inactive time between commands
* - Check for maximum inactive time between stepper commands
* - Check if pin CHDK needs to go LOW
* - Check for KILL button held down
* - Check for HOME button held down
* - Check if cooling fan needs to be switched on
* - Check if an idle but hot extruder needs filament extruded (EXTRUDER_RUNOUT_PREVENT)
*/
void manage_inactivity(bool ignore_stepper_queue/*=false*/) {
#if HAS_FILRUNOUT
if (IS_SD_PRINTING && !(READ(FILRUNOUT_PIN) ^ FIL_RUNOUT_INVERTING))
filrunout();
#endif
if (commands_in_queue < BUFSIZE) get_available_commands();
millis_t ms = millis();
if (max_inactive_time && ms > previous_cmd_ms + max_inactive_time) kill(PSTR(MSG_KILLED));
if (stepper_inactive_time && ms > previous_cmd_ms + stepper_inactive_time
&& !ignore_stepper_queue && !blocks_queued()) {
#if ENABLED(DISABLE_INACTIVE_X)
disable_x();
#endif
#if ENABLED(DISABLE_INACTIVE_Y)
disable_y();
#endif
#if ENABLED(DISABLE_INACTIVE_Z)
disable_z();
#endif
#if ENABLED(DISABLE_INACTIVE_E)
disable_e0();
disable_e1();
disable_e2();
disable_e3();
#endif
}
#ifdef CHDK // Check if pin should be set to LOW after M240 set it to HIGH
if (chdkActive && ms > chdkHigh + CHDK_DELAY) {
chdkActive = false;
WRITE(CHDK, LOW);
}
#endif
#if HAS_KILL
// Check if the kill button was pressed and wait just in case it was an accidental
// key kill key press
// -------------------------------------------------------------------------------
static int killCount = 0; // make the inactivity button a bit less responsive
const int KILL_DELAY = 750;
if (!READ(KILL_PIN))
killCount++;
else if (killCount > 0)
killCount--;
// Exceeded threshold and we can confirm that it was not accidental
// KILL the machine
// ----------------------------------------------------------------
if (killCount >= KILL_DELAY) kill(PSTR(MSG_KILLED));
#endif
#if HAS_HOME
// Check to see if we have to home, use poor man's debouncer
// ---------------------------------------------------------
static int homeDebounceCount = 0; // poor man's debouncing count
const int HOME_DEBOUNCE_DELAY = 2500;
if (!READ(HOME_PIN)) {
if (!homeDebounceCount) {
enqueue_and_echo_commands_P(PSTR("G28"));
LCD_MESSAGEPGM(MSG_AUTO_HOME);
}
if (homeDebounceCount < HOME_DEBOUNCE_DELAY)
homeDebounceCount++;
else
homeDebounceCount = 0;
}
#endif
#if HAS_CONTROLLERFAN
controllerFan(); // Check if fan should be turned on to cool stepper drivers down
#endif
#if ENABLED(EXTRUDER_RUNOUT_PREVENT)
if (ms > previous_cmd_ms + (EXTRUDER_RUNOUT_SECONDS) * 1000)
if (degHotend(active_extruder) > EXTRUDER_RUNOUT_MINTEMP) {
bool oldstatus;
switch (active_extruder) {
case 0:
oldstatus = E0_ENABLE_READ;
enable_e0();
break;
#if EXTRUDERS > 1
case 1:
oldstatus = E1_ENABLE_READ;
enable_e1();
break;
#if EXTRUDERS > 2
case 2:
oldstatus = E2_ENABLE_READ;
enable_e2();
break;
#if EXTRUDERS > 3
case 3:
oldstatus = E3_ENABLE_READ;
enable_e3();
break;
#endif
#endif
#endif
}
float oldepos = current_position[E_AXIS], oldedes = destination[E_AXIS];
plan_buffer_line(destination[X_AXIS], destination[Y_AXIS], destination[Z_AXIS],
destination[E_AXIS] + (EXTRUDER_RUNOUT_EXTRUDE) * (EXTRUDER_RUNOUT_ESTEPS) / axis_steps_per_unit[E_AXIS],
(EXTRUDER_RUNOUT_SPEED) / 60. * (EXTRUDER_RUNOUT_ESTEPS) / axis_steps_per_unit[E_AXIS], active_extruder);
current_position[E_AXIS] = oldepos;
destination[E_AXIS] = oldedes;
plan_set_e_position(oldepos);
previous_cmd_ms = ms; // refresh_cmd_timeout()
st_synchronize();
switch (active_extruder) {
case 0:
E0_ENABLE_WRITE(oldstatus);
break;
#if EXTRUDERS > 1
case 1:
E1_ENABLE_WRITE(oldstatus);
break;
#if EXTRUDERS > 2
case 2:
E2_ENABLE_WRITE(oldstatus);
break;
#if EXTRUDERS > 3
case 3:
E3_ENABLE_WRITE(oldstatus);
break;
#endif
#endif
#endif
}
}
#endif
#if ENABLED(DUAL_X_CARRIAGE)
// handle delayed move timeout
if (delayed_move_time && ms > delayed_move_time + 1000 && IsRunning()) {
// travel moves have been received so enact them
delayed_move_time = 0xFFFFFFFFUL; // force moves to be done
set_destination_to_current();
prepare_move();
}
#endif
#if ENABLED(TEMP_STAT_LEDS)
handle_status_leds();
#endif
check_axes_activity();
}
void kill(const char* lcd_msg) {
#if ENABLED(ULTRA_LCD)
lcd_setalertstatuspgm(lcd_msg);
#else
UNUSED(lcd_msg);
#endif
cli(); // Stop interrupts
disable_all_heaters();
disable_all_steppers();
#if HAS_POWER_SWITCH
pinMode(PS_ON_PIN, INPUT);
#endif
SERIAL_ERROR_START;
SERIAL_ERRORLNPGM(MSG_ERR_KILLED);
// FMC small patch to update the LCD before ending
sei(); // enable interrupts
for (int i = 5; i--; lcd_update()) delay(200); // Wait a short time
cli(); // disable interrupts
suicide();
while (1) {
#if ENABLED(USE_WATCHDOG)
watchdog_reset();
#endif
} // Wait for reset
}
#if ENABLED(FILAMENT_RUNOUT_SENSOR)
void filrunout() {
if (!filrunoutEnqueued) {
filrunoutEnqueued = true;
enqueue_and_echo_commands_P(PSTR(FILAMENT_RUNOUT_SCRIPT));
st_synchronize();
}
}
#endif // FILAMENT_RUNOUT_SENSOR
#if ENABLED(FAST_PWM_FAN)
void setPwmFrequency(uint8_t pin, int val) {
val &= 0x07;
switch (digitalPinToTimer(pin)) {
#if defined(TCCR0A)
case TIMER0A:
case TIMER0B:
// TCCR0B &= ~(_BV(CS00) | _BV(CS01) | _BV(CS02));
// TCCR0B |= val;
break;
#endif
#if defined(TCCR1A)
case TIMER1A:
case TIMER1B:
// TCCR1B &= ~(_BV(CS10) | _BV(CS11) | _BV(CS12));
// TCCR1B |= val;
break;
#endif
#if defined(TCCR2)
case TIMER2:
case TIMER2:
TCCR2 &= ~(_BV(CS10) | _BV(CS11) | _BV(CS12));
TCCR2 |= val;
break;
#endif
#if defined(TCCR2A)
case TIMER2A:
case TIMER2B:
TCCR2B &= ~(_BV(CS20) | _BV(CS21) | _BV(CS22));
TCCR2B |= val;
break;
#endif
#if defined(TCCR3A)
case TIMER3A:
case TIMER3B:
case TIMER3C:
TCCR3B &= ~(_BV(CS30) | _BV(CS31) | _BV(CS32));
TCCR3B |= val;
break;
#endif
#if defined(TCCR4A)
case TIMER4A:
case TIMER4B:
case TIMER4C:
TCCR4B &= ~(_BV(CS40) | _BV(CS41) | _BV(CS42));
TCCR4B |= val;
break;
#endif
#if defined(TCCR5A)
case TIMER5A:
case TIMER5B:
case TIMER5C:
TCCR5B &= ~(_BV(CS50) | _BV(CS51) | _BV(CS52));
TCCR5B |= val;
break;
#endif
}
}
#endif // FAST_PWM_FAN
void Stop() {
disable_all_heaters();
if (IsRunning()) {
Running = false;
Stopped_gcode_LastN = gcode_LastN; // Save last g_code for restart
SERIAL_ERROR_START;
SERIAL_ERRORLNPGM(MSG_ERR_STOPPED);
LCD_MESSAGEPGM(MSG_STOPPED);
}
}
/**
* Set target_extruder from the T parameter or the active_extruder
*
* Returns TRUE if the target is invalid
*/
bool setTargetedHotend(int code) {
target_extruder = active_extruder;
if (code_seen('T')) {
target_extruder = code_value_short();
if (target_extruder >= EXTRUDERS) {
SERIAL_ECHO_START;
SERIAL_CHAR('M');
SERIAL_ECHO(code);
SERIAL_ECHOPGM(" " MSG_INVALID_EXTRUDER " ");
SERIAL_ECHOLN((int)target_extruder);
return true;
}
}
return false;
}
float calculate_volumetric_multiplier(float diameter) {
if (!volumetric_enabled || diameter == 0) return 1.0;
float d2 = diameter * 0.5;
return 1.0 / (M_PI * d2 * d2);
}
void calculate_volumetric_multipliers() {
for (int i = 0; i < EXTRUDERS; i++)
volumetric_multiplier[i] = calculate_volumetric_multiplier(filament_size[i]);
}
/**
* Start the print job timer
*
* The print job is only started if all extruders have their target temp at zero
* otherwise the print job timew would be reset everytime a M109 is received.
*
* @param t start timer timestamp
*
* @return true if the timer was started at function call
*/
bool print_job_start(millis_t t /* = 0 */) {
for (int i = 0; i < EXTRUDERS; i++) if (degTargetHotend(i) > 0) return false;
print_job_start_ms = (t) ? t : millis();
print_job_stop_ms = 0;
return true;
}
/**
* Check if the running print job has finished and stop the timer
*
* When the target temperature for all extruders is zero then we assume that the
* print job has finished printing. There are some special conditions under which
* this assumption may not be valid: If during a print job for some reason the
* user decides to bring a nozzle temp down and only then heat the other afterwards.
*
* @param force stops the timer ignoring all pre-checks
*
* @return boolean true if the print job has finished printing
*/
bool print_job_stop(bool force /* = false */) {
if (!print_job_start_ms) return false;
if (!force) for (int i = 0; i < EXTRUDERS; i++) if (degTargetHotend(i) > 0) return false;
print_job_stop_ms = millis();
return true;
}
/**
* Output the print job timer in seconds
*
* @return the number of seconds
*/
millis_t print_job_timer() {
if (!print_job_start_ms) return 0;
return (((print_job_stop_ms > print_job_start_ms)
? print_job_stop_ms : millis()) - print_job_start_ms) / 1000;
}