Arduino/Repetier/Extruder.cpp

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/*
This file is part of Repetier-Firmware.
Repetier-Firmware is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
Repetier-Firmware is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with Repetier-Firmware. If not, see <http://www.gnu.org/licenses/>.
This firmware is a nearly complete rewrite of the sprinter firmware
by kliment (https://github.com/kliment/Sprinter)
which based on Tonokip RepRap firmware rewrite based off of Hydra-mmm firmware.
*/
#include "Repetier.h"
uint8_t manageMonitor = 0; ///< Temp. we want to monitor with our host. 1+NUM_EXTRUDER is heated bed
unsigned int counterPeriodical = 0;
volatile uint8_t executePeriodical = 0;
uint8_t counter250ms = 25;
#if FEATURE_DITTO_PRINTING
uint8_t Extruder::dittoMode = 0;
#endif
#if MIXING_EXTRUDER > 0
int Extruder::mixingS;
uint8_t Extruder::mixingDir = 10;
uint8_t Extruder::activeMixingExtruder = 0;
#endif // MIXING_EXTRUDER
#ifdef SUPPORT_MAX6675
extern int16_t read_max6675(uint8_t ss_pin);
#endif
#ifdef SUPPORT_MAX31855
extern int16_t read_max31855(uint8_t ss_pin);
#endif
#if ANALOG_INPUTS > 0
const uint8 osAnalogInputChannels[] PROGMEM = ANALOG_INPUT_CHANNELS;
volatile uint osAnalogInputValues[ANALOG_INPUTS];
#endif
#ifdef USE_GENERIC_THERMISTORTABLE_1
short temptable_generic1[GENERIC_THERM_NUM_ENTRIES][2];
#endif
#ifdef USE_GENERIC_THERMISTORTABLE_2
short temptable_generic2[GENERIC_THERM_NUM_ENTRIES][2];
#endif
#ifdef USE_GENERIC_THERMISTORTABLE_3
short temptable_generic3[GENERIC_THERM_NUM_ENTRIES][2];
#endif
/** Makes updates to temperatures and heater state every call.
Is called every 100ms.
*/
static uint8_t extruderTempErrors = 0;
void Extruder::manageTemperatures()
{
#if FEATURE_WATCHDOG
HAL::pingWatchdog();
#endif // FEATURE_WATCHDOG
uint8_t errorDetected = 0;
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#ifdef RED_BLUE_STATUS_LEDS
bool hot = false;
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#endif
bool newDefectFound = false;
millis_t time = HAL::timeInMilliseconds(); // compare time for decouple tests
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#if NUM_TEMPERATURE_LOOPS > 0
for(uint8_t controller = 0; controller < NUM_TEMPERATURE_LOOPS; controller++)
{
TemperatureController *act = tempController[controller];
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// Get Temperature
act->updateCurrentTemperature();
#if FAN_THERMO_PIN > -1
// Special case thermistor controlled fan
if(act == &thermoController) {
if(act->currentTemperatureC < Printer::thermoMinTemp)
pwm_pos[PWM_FAN_THERMO] = 0;
else if(act->currentTemperatureC > Printer::thermoMaxTemp)
pwm_pos[PWM_FAN_THERMO] = FAN_THERMO_MAX_PWM;
else {
// Interpolate target speed
float out = FAN_THERMO_MIN_PWM + (FAN_THERMO_MAX_PWM-FAN_THERMO_MIN_PWM) * (act->currentTemperatureC - Printer::thermoMinTemp) / (Printer::thermoMaxTemp - Printer::thermoMinTemp);
if(out > 255)
pwm_pos[PWM_FAN_THERMO] = FAN_THERMO_MAX_PWM;
else
pwm_pos[PWM_FAN_THERMO] = static_cast<uint8_t>(out);
}
continue;
}
#endif
// Handle automatic cooling of extruders
if(controller < NUM_EXTRUDER)
{
#if ((SHARED_COOLER && NUM_EXTRUDER >= 2 && EXT0_EXTRUDER_COOLER_PIN == EXT1_EXTRUDER_COOLER_PIN) || SHARED_COOLER_BOARD_EXT) && EXT0_EXTRUDER_COOLER_PIN > -1
if(controller == 0)
{
bool enable = false;
for(uint8_t j = 0; j < NUM_EXTRUDER; j++)
{
if(tempController[j]->currentTemperatureC >= EXTRUDER_FAN_COOL_TEMP || tempController[j]->targetTemperatureC >= EXTRUDER_FAN_COOL_TEMP)
{
enable = true;
break;
}
}
#if SHARED_COOLER_BOARD_EXT
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if(pwm_pos[PWM_BOARD_FAN]) enable = true;
#endif
extruder[0].coolerPWM = (enable ? extruder[0].coolerSpeed : 0);
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} // controller == 0
#else
if(act->currentTemperatureC < EXTRUDER_FAN_COOL_TEMP && act->targetTemperatureC < EXTRUDER_FAN_COOL_TEMP)
extruder[controller].coolerPWM = 0;
else
extruder[controller].coolerPWM = extruder[controller].coolerSpeed;
#endif // NUM_EXTRUDER
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} // extruder controller
// do skip temperature control while auto tuning is in progress
if(controller == autotuneIndex) continue;
#if MIXING_EXTRUDER
if(controller > 0 && controller < NUM_EXTRUDER) continue; // Mixing extruder only test for ext 0
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#endif // MIXING_EXTRUDER
// Check for obvious sensor errors
if(act->currentTemperatureC < MIN_DEFECT_TEMPERATURE || act->currentTemperatureC > MAX_DEFECT_TEMPERATURE) // no temp sensor or short in sensor, disable heater
{
errorDetected = 1;
if(extruderTempErrors < 10) // Ignore short temporary failures
extruderTempErrors++;
else
{
act->flags |= TEMPERATURE_CONTROLLER_FLAG_SENSDEFECT;
if(!Printer::isAnyTempsensorDefect())
{
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newDefectFound = true;
Printer::setAnyTempsensorDefect();
reportTempsensorError();
}
EVENT_HEATER_DEFECT(controller);
}
}
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#if HAVE_HEATED_BED
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else if(controller == HEATED_BED_INDEX && Extruder::getHeatedBedTemperature() > HEATED_BED_MAX_TEMP + 5) {
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errorDetected = 1;
if(extruderTempErrors < 10) // Ignore short temporary failures
extruderTempErrors++;
else
{
act->flags |= TEMPERATURE_CONTROLLER_FLAG_SENSDEFECT;
Com::printErrorFLN(PSTR("Heated bed exceeded max temperature!"));
if(!Printer::isAnyTempsensorDefect())
{
newDefectFound = true;
Printer::setAnyTempsensorDefect();
reportTempsensorError();
}
EVENT_HEATER_DEFECT(controller);
}
}
#endif // HAVE_HEATED_BED
#ifdef RED_BLUE_STATUS_LEDS
if(act->currentTemperatureC > 50)
hot = true;
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#endif // RED_BLUE_STATUS_LEDS
if(Printer::isAnyTempsensorDefect()) continue;
uint8_t on = act->currentTemperatureC >= act->targetTemperatureC ? LOW : HIGH;
// Make a sound if alarm was set on reaching target temperature
if(!on && act->isAlarm())
{
beep(50 * (controller + 1), 3);
act->setAlarm(false); //reset alarm
}
// Run test if heater and sensor are decoupled
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bool decoupleTestRequired = !errorDetected && act->decoupleTestPeriod > 0 && (time - act->lastDecoupleTest) > act->decoupleTestPeriod; // time enough for temperature change?
if(decoupleTestRequired && act->isDecoupleFullOrHold() && Printer::isPowerOn()) // Only test when powered
{
if(act->isDecoupleFull()) // Phase 1: Heating fully until target range is reached
{
if(act->currentTemperatureC - act->lastDecoupleTemp < DECOUPLING_TEST_MIN_TEMP_RISE) // failed test
{
extruderTempErrors++;
errorDetected = 1;
if(extruderTempErrors > 10) // Ignore short temporary failures
{
act->flags |= TEMPERATURE_CONTROLLER_FLAG_SENSDECOUPLED;
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if(!Printer::isAnyTempsensorDefect())
{
Printer::setAnyTempsensorDefect();
newDefectFound = true;
}
UI_ERROR_P(Com::tHeaterDecoupled);
Com::printErrorFLN(Com::tHeaterDecoupledWarning);
Com::printF(PSTR("Error:Temp. raised to slow. Rise = "),act->currentTemperatureC - act->lastDecoupleTemp);
Com::printF(PSTR(" after "),(int32_t)(time-act->lastDecoupleTest));
Com::printFLN(PSTR(" ms"));
EVENT_HEATER_DECOUPLED(controller);
}
}
else
{
act->stopDecouple();
act->startFullDecouple(time);
}
}
else // Phase 2: Holding temperature inside a target corridor
{
if(fabs(act->currentTemperatureC - act->targetTemperatureC) > DECOUPLING_TEST_MAX_HOLD_VARIANCE) // failed test
{
extruderTempErrors++;
errorDetected = 1;
if(extruderTempErrors > 10) // Ignore short temporary failures
{
act->flags |= TEMPERATURE_CONTROLLER_FLAG_SENSDECOUPLED;
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if(!Printer::isAnyTempsensorDefect())
{
Printer::setAnyTempsensorDefect();
newDefectFound = true;
}
UI_ERROR_P(Com::tHeaterDecoupled);
Com::printErrorFLN(Com::tHeaterDecoupledWarning);
Com::printF(PSTR("Error:Could not hold temperature "),act->lastDecoupleTemp);
Com::printF(PSTR(" measured "),act->currentTemperatureC);
Com::printFLN(PSTR(" deg. C"));
EVENT_HEATER_DECOUPLED(controller);
}
}
else
{
act->lastDecoupleTest = time - act->decoupleTestPeriod + 1000; // once running test every second
}
}
}
#if TEMP_PID
act->tempArray[act->tempPointer++] = act->currentTemperatureC;
act->tempPointer &= 3;
uint8_t output = 0;
float error = act->targetTemperatureC - act->currentTemperatureC;
if(act->targetTemperatureC < 20.0f) // heating is off
{
output = 0; // off is off, even if damping term wants a heat peak!
act->stopDecouple();
}
else if(error > PID_CONTROL_RANGE) // Phase 1: full heating until control range reached
{
output = act->pidMax;
act->startFullDecouple(time);
}
else if(error < -PID_CONTROL_RANGE) // control range left upper side!
output = 0;
else // control range handle by heat manager
{
if(act->heatManager == HTR_PID)
{
act->startHoldDecouple(time);
float pidTerm = act->pidPGain * error;
act->tempIState = constrain(act->tempIState + error, act->tempIStateLimitMin, act->tempIStateLimitMax);
pidTerm += act->pidIGain * act->tempIState * 0.1; // 0.1 = 10Hz
float dgain = act->pidDGain * (act->tempArray[act->tempPointer] - act->currentTemperatureC) * 3.333f;
pidTerm += dgain;
#if SCALE_PID_TO_MAX == 1
pidTerm = (pidTerm * act->pidMax) * 0.0039215;
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#endif // SCALE_PID_TO_MAX
output = constrain((int)pidTerm, 0, act->pidMax);
}
else if(act->heatManager == HTR_DEADTIME) // dead-time control
{
act->startHoldDecouple(time);
float raising = 3.333 * (act->currentTemperatureC - act->tempArray[act->tempPointer]); // raising dT/dt, 3.33 = reciproke of time interval (300 ms)
act->tempIState = 0.25 * (3.0 * act->tempIState + raising); // damp raising
output = (act->currentTemperatureC + act->tempIState * act->deadTime > act->targetTemperatureC ? 0 : act->pidDriveMax);
}
else // bang bang and slow bang bang
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#endif // TEMP_PID
if(act->heatManager == HTR_SLOWBANG) // Bang-bang with reduced change frequency to save relais life
{
if (time - act->lastTemperatureUpdate > HEATED_BED_SET_INTERVAL)
{
output = (on ? act->pidMax : 0);
act->lastTemperatureUpdate = time;
if(on) act->startFullDecouple(time);
else act->stopDecouple();
}
else continue;
}
else // Fast Bang-Bang fallback
{
output = (on ? act->pidMax : 0);
if(on) act->startFullDecouple(time);
else act->stopDecouple();
}
} // Temperatur control
#ifdef MAXTEMP
if(act->currentTemperatureC > MAXTEMP) // Force heater off if MAXTEMP is exceeded
output = 0;
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#endif // MAXTEMP
pwm_pos[act->pwmIndex] = output; // set pwm signal
#if LED_PIN > -1
if(act == &Extruder::current->tempControl)
WRITE(LED_PIN,on);
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#endif // LED_PIN
} // for controller
#ifdef RED_BLUE_STATUS_LEDS
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if(Printer::isAnyTempsensorDefect())
{
WRITE(BLUE_STATUS_LED,HIGH);
WRITE(RED_STATUS_LED,HIGH);
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}
else
{
WRITE(BLUE_STATUS_LED,!hot);
WRITE(RED_STATUS_LED,hot);
}
#endif // RED_BLUE_STATUS_LEDS
if(errorDetected == 0 && extruderTempErrors > 0)
extruderTempErrors--;
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if(newDefectFound)
{
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Com::printFLN(PSTR("Disabling all heaters due to detected sensor defect."));
for(uint8_t i = 0; i < NUM_TEMPERATURE_LOOPS; i++)
{
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tempController[i]->targetTemperatureC = 0;
pwm_pos[tempController[i]->pwmIndex] = 0;
}
#if defined(KILL_IF_SENSOR_DEFECT) && KILL_IF_SENSOR_DEFECT > 0
if(!Printer::debugDryrun() && PrintLine::linesCount > 0) // kill printer if actually printing
{
#if SDSUPPORT
sd.stopPrint();
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#endif // SDSUPPORT
Printer::kill(0);
}
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#endif // KILL_IF_SENSOR_DEFECT
Printer::debugSet(8); // Go into dry mode
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} // any sensor defect
#endif // NUM_TEMPERATURE_LOOPS
}
void TemperatureController::waitForTargetTemperature()
{
if(targetTemperatureC < 30) return;
if(Printer::debugDryrun()) return;
millis_t time = HAL::timeInMilliseconds();
while(true)
{
if( (HAL::timeInMilliseconds() - time) > 1000 ) //Print Temp Reading every 1 second while heating up.
{
Commands::printTemperatures();
time = HAL::timeInMilliseconds();
}
Commands::checkForPeriodicalActions(true);
if(fabs(targetTemperatureC - currentTemperatureC) <= 1)
return;
}
}
/* For pausing we negate target temperature, so negative value means paused extruder.
Since temp. is negative no heating will occur. */
void Extruder::pauseExtruders()
{
disableAllExtruderMotors();
for(fast8_t i = 0; i < NUM_EXTRUDER; i++)
{
if(extruder[i].tempControl.targetTemperatureC > 0)
extruder[i].tempControl.targetTemperatureC = -extruder[i].tempControl.targetTemperatureC;
}
}
void Extruder::unpauseExtruders()
{
// activate temperatures
for(fast8_t i = 0; i < NUM_EXTRUDER; i++)
{
if(extruder[i].tempControl.targetTemperatureC < 0)
extruder[i].tempControl.targetTemperatureC = -extruder[i].tempControl.targetTemperatureC;
}
for(fast8_t i = 0; i < NUM_EXTRUDER; i++)
extruder[i].tempControl.waitForTargetTemperature();
}
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void TemperatureController::resetAllErrorStates() {
#if NUM_TEMPERATURE_LOOPS > 0
for(int i = 0;i < NUM_TEMPERATURE_LOOPS; i++) {
tempController[i]->removeErrorStates();
}
#endif
}
#if EXTRUDER_JAM_CONTROL
void TemperatureController::setJammed(bool on)
{
if(on)
{
flags |= TEMPERATURE_CONTROLLER_FLAG_JAM;
Printer::setInterruptEvent(PRINTER_INTERRUPT_EVENT_JAM_DETECTED, true);
}
else flags &= ~(TEMPERATURE_CONTROLLER_FLAG_JAM);
}
void Extruder::markAllUnjammed()
{
for(fast8_t i = 0; i < NUM_EXTRUDER; i++)
{
extruder[i].tempControl.setJammed(false);
extruder[i].tempControl.setSlowedDown(false);
extruder[i].resetJamSteps();
}
if(Printer::feedrateMultiply == JAM_SLOWDOWN_TO)
Commands::changeFeedrateMultiply(100);
Printer::unsetAnyTempsensorDefect(); // stop alarm
Com::printInfoFLN(PSTR("Marked all extruders as unjammed."));
Printer::setUIErrorMessage(false);
}
void Extruder::resetJamSteps()
{
jamStepsOnSignal = jamStepsSinceLastSignal;
jamStepsSinceLastSignal = 0;
Printer::setInterruptEvent(PRINTER_INTERRUPT_EVENT_JAM_SIGNAL0 + id, false);
}
#endif
void Extruder::initHeatedBed()
{
#if HAVE_HEATED_BED
#if TEMP_PID
heatedBedController.updateTempControlVars();
#endif
#endif
}
#if defined(USE_GENERIC_THERMISTORTABLE_1) || defined(USE_GENERIC_THERMISTORTABLE_2) || defined(USE_GENERIC_THERMISTORTABLE_3)
void createGenericTable(short table[GENERIC_THERM_NUM_ENTRIES][2],short minTemp,short maxTemp,float beta,float r0,float t0,float r1,float r2)
{
t0 += 273.15f;
float rs, vs;
if(r1==0)
{
rs = r2;
vs = GENERIC_THERM_VREF;
}
else
{
vs =static_cast<float>((GENERIC_THERM_VREF * r1) / (r1 + r2));
rs = (r2 * r1) / (r1 + r2);
}
float k = r0 * exp(-beta / t0);
float delta = (maxTemp-minTemp) / (GENERIC_THERM_NUM_ENTRIES - 1.0f);
for(uint8_t i = 0; i < GENERIC_THERM_NUM_ENTRIES; i++)
{
#if FEATURE_WATCHDOG
HAL::pingWatchdog();
#endif // FEATURE_WATCHDOG
float t = maxTemp - i * delta;
float r = exp(beta / (t + 272.65)) * k;
float v = 4092 * r * vs / ((rs + r) * GENERIC_THERM_VREF);
int adc = static_cast<int>(v);
t *= 8;
if(adc > 4092) adc = 4092;
table[i][0] = (adc >> (ANALOG_REDUCE_BITS));
table[i][1] = static_cast<int>(t);
#ifdef DEBUG_GENERIC
Com::printF(Com::tGenTemp,table[i][0]);
Com::printFLN(Com::tComma,table[i][1]);
#endif
}
}
#endif
/** \brief Initalizes all extruder.
Updates the pin configuration needed for the extruder and activates extruder 0.
Starts a interrupt based analog input reader, which is used by simple thermistors
for temperature reading.
*/
void Extruder::initExtruder()
{
uint8_t i;
Extruder::current = &extruder[0];
#ifdef USE_GENERIC_THERMISTORTABLE_1
createGenericTable(temptable_generic1,GENERIC_THERM1_MIN_TEMP,GENERIC_THERM1_MAX_TEMP,GENERIC_THERM1_BETA,GENERIC_THERM1_R0,GENERIC_THERM1_T0,GENERIC_THERM1_R1,GENERIC_THERM1_R2);
#endif
#ifdef USE_GENERIC_THERMISTORTABLE_2
createGenericTable(temptable_generic2,GENERIC_THERM2_MIN_TEMP,GENERIC_THERM2_MAX_TEMP,GENERIC_THERM2_BETA,GENERIC_THERM2_R0,GENERIC_THERM2_T0,GENERIC_THERM2_R1,GENERIC_THERM2_R2);
#endif
#ifdef USE_GENERIC_THERMISTORTABLE_3
createGenericTable(temptable_generic3,GENERIC_THERM3_MIN_TEMP,GENERIC_THERM3_MAX_TEMP,GENERIC_THERM3_BETA,GENERIC_THERM3_R0,GENERIC_THERM3_T0,GENERIC_THERM3_R1,GENERIC_THERM3_R2);
#endif
#if defined(EXT0_STEP_PIN) && EXT0_STEP_PIN > -1 && NUM_EXTRUDER > 0
SET_OUTPUT(EXT0_DIR_PIN);
SET_OUTPUT(EXT0_STEP_PIN);
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#if defined(EXT0_MIRROR_STEPPER) && EXT0_MIRROR_STEPPER
SET_OUTPUT(EXT0_DIR2_PIN);
SET_OUTPUT(EXT0_STEP2_PIN);
SET_OUTPUT(EXT0_ENABLE2_PIN);
WRITE(EXT0_ENABLE2_PIN,!EXT0_ENABLE_ON);
#endif
#endif
#if defined(EXT1_STEP_PIN) && EXT1_STEP_PIN > -1 && NUM_EXTRUDER > 1
SET_OUTPUT(EXT1_DIR_PIN);
SET_OUTPUT(EXT1_STEP_PIN);
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#if defined(EXT1_MIRROR_STEPPER) && EXT1_MIRROR_STEPPER
SET_OUTPUT(EXT1_DIR2_PIN);
SET_OUTPUT(EXT1_STEP2_PIN);
SET_OUTPUT(EXT1_ENABLE2_PIN);
WRITE(EXT1_ENABLE2_PIN,!EXT1_ENABLE_ON);
#endif
#endif
#if defined(EXT2_STEP_PIN) && EXT2_STEP_PIN > -1 && NUM_EXTRUDER > 2
SET_OUTPUT(EXT2_DIR_PIN);
SET_OUTPUT(EXT2_STEP_PIN);
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#if defined(EXT2_MIRROR_STEPPER) && EXT2_MIRROR_STEPPER
SET_OUTPUT(EXT2_DIR2_PIN);
SET_OUTPUT(EXT2_STEP2_PIN);
SET_OUTPUT(EXT2_ENABLE2_PIN);
WRITE(EXT2_ENABLE2_PIN,!EXT2_ENABLE_ON);
#endif
#endif
#if defined(EXT3_STEP_PIN) && EXT3_STEP_PIN > -1 && NUM_EXTRUDER > 3
SET_OUTPUT(EXT3_DIR_PIN);
SET_OUTPUT(EXT3_STEP_PIN);
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#if defined(EXT3_MIRROR_STEPPER) && EXT3_MIRROR_STEPPER
SET_OUTPUT(EXT3_DIR2_PIN);
SET_OUTPUT(EXT3_STEP2_PIN);
SET_OUTPUT(EXT3_ENABLE2_PIN);
WRITE(EXT3_ENABLE2_PIN,!EXT3_ENABLE_ON);
#endif
#endif
#if defined(EXT4_STEP_PIN) && EXT4_STEP_PIN > -1 && NUM_EXTRUDER > 4
SET_OUTPUT(EXT4_DIR_PIN);
SET_OUTPUT(EXT4_STEP_PIN);
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#if defined(EXT4_MIRROR_STEPPER) && EXT4_MIRROR_STEPPER
SET_OUTPUT(EXT4_DIR2_PIN);
SET_OUTPUT(EXT4_STEP2_PIN);
SET_OUTPUT(EXT4_ENABLE2_PIN);
WRITE(EXT4_ENABLE2_PIN,!EXT4_ENABLE_ON);
#endif
#endif
#if defined(EXT5_STEP_PIN) && EXT5_STEP_PIN > -1 && NUM_EXTRUDER > 5
SET_OUTPUT(EXT5_DIR_PIN);
SET_OUTPUT(EXT5_STEP_PIN);
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#if defined(EXT5_MIRROR_STEPPER) && EXT5_MIRROR_STEPPER
SET_OUTPUT(EXT5_DIR2_PIN);
SET_OUTPUT(EXT5_STEP2_PIN);
SET_OUTPUT(EXT5_ENABLE2_PIN);
WRITE(EXT5_ENABLE2_PIN,!EXT5_ENABLE_ON);
#endif
#endif
for(i = 0; i < NUM_EXTRUDER; ++i)
{
Extruder *act = &extruder[i];
if(act->enablePin > -1)
{
HAL::pinMode(act->enablePin, OUTPUT);
HAL::digitalWrite(act->enablePin,!act->enableOn);
}
act->tempControl.lastTemperatureUpdate = HAL::timeInMilliseconds();
#if defined(SUPPORT_MAX6675) || defined(SUPPORT_MAX31855)
if(act->tempControl.sensorType == 101 || act->tempControl.sensorType == 102)
{
WRITE(SCK_PIN, 0);
SET_OUTPUT(SCK_PIN);
WRITE(MOSI_PIN, 1);
SET_OUTPUT(MOSI_PIN);
WRITE(MISO_PIN, 1);
SET_INPUT(MISO_PIN);
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//SET_OUTPUT(SS);
//WRITE(SS, HIGH);
HAL::pinMode(SS, OUTPUT);
HAL::digitalWrite(SS, 1);
HAL::pinMode(act->tempControl.sensorPin, OUTPUT);
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HAL::digitalWrite(act->tempControl.sensorPin, 1);
}
#endif
}
#if HEATED_BED_HEATER_PIN > -1
SET_OUTPUT(HEATED_BED_HEATER_PIN);
WRITE(HEATED_BED_HEATER_PIN, HEATER_PINS_INVERTED);
Extruder::initHeatedBed();
#endif
HAL::analogStart();
}
void TemperatureController::updateTempControlVars()
{
#if TEMP_PID
if(heatManager == HTR_PID && pidIGain != 0) // prevent division by zero
{
tempIStateLimitMax = (float)pidDriveMax * 10.0f / pidIGain;
tempIStateLimitMin = (float)pidDriveMin * 10.0f / pidIGain;
}
#endif
}
/** \brief Select extruder ext_num.
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This function changes and initializes a new extruder. This is also called, after the eeprom values are changed.
*/
void Extruder::selectExtruderById(uint8_t extruderId)
{
#if NUM_EXTRUDER > 0
#if MIXING_EXTRUDER
if(extruderId >= VIRTUAL_EXTRUDER)
extruderId = 0;
activeMixingExtruder = extruderId;
for(uint8_t i = 0; i < NUM_EXTRUDER; i++)
Extruder::setMixingWeight(i, extruder[i].virtualWeights[extruderId]);
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Com::printFLN(PSTR("SelectExtruder:"), static_cast<int>(extruderId));
extruderId = 0;
#endif
if(extruderId >= NUM_EXTRUDER)
extruderId = 0;
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#if !MIXING_EXTRUDER
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Com::printFLN(PSTR("SelectExtruder:"), static_cast<int>(extruderId));
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#endif
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if(Printer::isHomed() && extruder[extruderId].zOffset < Extruder::current->zOffset) { // prevent extruder from hitting bed
Printer::offsetZ = -extruder[extruderId].zOffset * Printer::invAxisStepsPerMM[Z_AXIS];
Printer::moveToReal(IGNORE_COORDINATE, IGNORE_COORDINATE, IGNORE_COORDINATE, IGNORE_COORDINATE, Printer::homingFeedrate[Z_AXIS]);
Commands::waitUntilEndOfAllMoves();
Printer::updateCurrentPosition(true);
}
#if NUM_EXTRUDER > 1 && MIXING_EXTRUDER == 0
bool executeSelect = false;
if(extruderId != Extruder::current->id)
{
GCode::executeFString(Extruder::current->deselectCommands);
executeSelect = true;
}
Commands::waitUntilEndOfAllMoves();
#endif
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float cx, cy, cz;
Printer::realPosition(cx, cy, cz);
float oldfeedrate = Printer::feedrate;
Extruder::current->extrudePosition = Printer::currentPositionSteps[E_AXIS];
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#if DUAL_X_AXIS
// Park current extruder
int32_t dualXPos = Printer::currentPositionSteps[X_AXIS] - Printer::xMinSteps;
if(Printer::isHomed())
PrintLine::moveRelativeDistanceInSteps(Extruder::current->xOffset - dualXPos, 0, 0, 0, EXTRUDER_SWITCH_XY_SPEED, true, false);
#endif
Extruder::current = &extruder[extruderId];
#ifdef SEPERATE_EXTRUDER_POSITIONS
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// Use separate extruder positions only if being told. Slic3r e.g. creates a continuous extruder position increment
Printer::currentPositionSteps[E_AXIS] = Extruder::current->extrudePosition;
#endif
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#if MIXING_EXTRUDER
recomputeMixingExtruderSteps();
#else
Printer::destinationSteps[E_AXIS] = Printer::currentPositionSteps[E_AXIS];
Printer::axisStepsPerMM[E_AXIS] = Extruder::current->stepsPerMM;
Printer::invAxisStepsPerMM[E_AXIS] = 1.0f / Printer::axisStepsPerMM[E_AXIS];
#endif
Printer::maxFeedrate[E_AXIS] = Extruder::current->maxFeedrate;
// max_start_speed_units_per_second[E_AXIS] = Extruder::current->maxStartFeedrate;
Printer::maxAccelerationMMPerSquareSecond[E_AXIS] = Printer::maxTravelAccelerationMMPerSquareSecond[E_AXIS] = Extruder::current->maxAcceleration;
Printer::maxTravelAccelerationStepsPerSquareSecond[E_AXIS] =
Printer::maxPrintAccelerationStepsPerSquareSecond[E_AXIS] = Printer::maxAccelerationMMPerSquareSecond[E_AXIS] * Printer::axisStepsPerMM[E_AXIS];
#if USE_ADVANCE
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Printer::maxExtruderSpeed = (ufast8_t)floor(HAL::maxExtruderTimerFrequency() / (Extruder::current->maxFeedrate * Extruder::current->stepsPerMM));
#if CPU_ARCH == ARCH_ARM
if(Printer::maxExtruderSpeed > 40) Printer::maxExtruderSpeed = 40;
#else
if(Printer::maxExtruderSpeed > 15) Printer::maxExtruderSpeed = 15;
#endif
float maxdist = Extruder::current->maxFeedrate * Extruder::current->maxFeedrate * 0.00013888 / Extruder::current->maxAcceleration;
maxdist -= Extruder::current->maxStartFeedrate * Extruder::current->maxStartFeedrate * 0.5 / Extruder::current->maxAcceleration;
float fmax = ((float)HAL::maxExtruderTimerFrequency() / ((float)Printer::maxExtruderSpeed * Printer::axisStepsPerMM[E_AXIS])); // Limit feedrate to interrupt speed
if(fmax < Printer::maxFeedrate[E_AXIS]) Printer::maxFeedrate[E_AXIS] = fmax;
#endif
Extruder::current->tempControl.updateTempControlVars();
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#if DUAL_X_AXIS
// Unpark new current extruder
if(executeSelect) {// Run only when changing
Commands::waitUntilEndOfAllMoves();
Printer::updateCurrentPosition(true);
GCode::executeFString(Extruder::current->selectCommands);
executeSelect = false;
}
Printer::currentPositionSteps[X_AXIS] = Extruder::current->xOffset - dualXPos;
if(Printer::isHomed())
PrintLine::moveRelativeDistanceInSteps(-Extruder::current->xOffset + dualXPos, 0, 0, 0, EXTRUDER_SWITCH_XY_SPEED, true, false);
Printer::currentPositionSteps[X_AXIS] = dualXPos + Printer::xMinSteps;
Printer::offsetX = 0;
Printer::updateCurrentPosition(true);
#else
Printer::offsetX = -Extruder::current->xOffset * Printer::invAxisStepsPerMM[X_AXIS];
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#endif
Printer::offsetY = -Extruder::current->yOffset * Printer::invAxisStepsPerMM[Y_AXIS];
Printer::offsetZ = -Extruder::current->zOffset * Printer::invAxisStepsPerMM[Z_AXIS];
Commands::changeFlowrateMultiply(Printer::extrudeMultiply); // needed to adjust extrusionFactor to possibly different diameter
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if(Printer::isHomed()) {
Printer::moveToReal(cx, cy, cz, IGNORE_COORDINATE, EXTRUDER_SWITCH_XY_SPEED);
}
Printer::feedrate = oldfeedrate;
Printer::updateCurrentPosition();
#if USE_ADVANCE
HAL::resetExtruderDirection();
#endif
#if NUM_EXTRUDER > 1 && MIXING_EXTRUDER == 0
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if(executeSelect) {// Run only when changing
Commands::waitUntilEndOfAllMoves();
GCode::executeFString(Extruder::current->selectCommands);
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}
#endif
#endif
}
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#if MIXING_EXTRUDER
void Extruder::recomputeMixingExtruderSteps() {
int32_t sum_w = 0;
float sum = 0;
for(fast8_t i = 0; i < NUM_EXTRUDER; i++) {
sum_w += extruder[i].mixingW;
sum += extruder[i].stepsPerMM * extruder[i].mixingW;
}
sum /= sum_w;
Printer::currentPositionSteps[E_AXIS] = Printer::currentPositionSteps[E_AXIS] * sum / Printer::axisStepsPerMM[E_AXIS]; // reposition according resolution change
Printer::destinationSteps[E_AXIS] = Printer::currentPositionSteps[E_AXIS];
Printer::axisStepsPerMM[E_AXIS] = sum;
Printer::invAxisStepsPerMM[E_AXIS] = 1.0f / Printer::axisStepsPerMM[E_AXIS];
}
#endif
void Extruder::setTemperatureForExtruder(float temperatureInCelsius, uint8_t extr, bool beep, bool wait)
{
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#if NUM_EXTRUDER > 0
#if MIXING_EXTRUDER || SHARED_EXTRUDER_HEATER
extr = 0; // map any virtual extruder number to 0
#endif // MIXING_EXTRUDER
bool alloffs = true;
for(uint8_t i = 0; i < NUM_EXTRUDER; i++)
if(tempController[i]->targetTemperatureC > 15) alloffs = false;
#ifdef MAXTEMP
if(temperatureInCelsius > MAXTEMP) temperatureInCelsius = MAXTEMP;
#endif
if(temperatureInCelsius < 0) temperatureInCelsius = 0;
TemperatureController *tc = tempController[extr];
if(tc->sensorType == 0) temperatureInCelsius = 0;
//if(temperatureInCelsius==tc->targetTemperatureC) return;
tc->setTargetTemperature(temperatureInCelsius);
tc->updateTempControlVars();
if(beep && temperatureInCelsius > MAX_ROOM_TEMPERATURE)
tc->setAlarm(true);
if(temperatureInCelsius >= EXTRUDER_FAN_COOL_TEMP) extruder[extr].coolerPWM = extruder[extr].coolerSpeed;
Com::printF(Com::tTargetExtr,extr,0);
Com::printFLN(Com::tColon,temperatureInCelsius,0);
#if FEATURE_DITTO_PRINTING
if(Extruder::dittoMode && extr == 0)
{
TemperatureController *tc2 = tempController[1];
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tc2->setTargetTemperature(temperatureInCelsius);
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tc2->updateTempControlVars();
if(temperatureInCelsius >= EXTRUDER_FAN_COOL_TEMP) extruder[1].coolerPWM = extruder[1].coolerSpeed;
#if NUM_EXTRUDER > 2
if(Extruder::dittoMode > 1 && extr == 0)
{
TemperatureController *tc2 = tempController[2];
tc2->setTargetTemperature(temperatureInCelsius);
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tc2->updateTempControlVars();
if(temperatureInCelsius >= EXTRUDER_FAN_COOL_TEMP) extruder[2].coolerPWM = extruder[2].coolerSpeed;
}
#endif
#if NUM_EXTRUDER > 3
if(Extruder::dittoMode > 2 && extr == 0)
{
TemperatureController *tc2 = tempController[3];
tc2->setTargetTemperature(temperatureInCelsius);
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tc2->updateTempControlVars();
if(temperatureInCelsius >= EXTRUDER_FAN_COOL_TEMP) extruder[3].coolerPWM = extruder[3].coolerSpeed;
}
#endif
}
#endif // FEATURE_DITTO_PRINTING
if(wait && temperatureInCelsius > MAX_ROOM_TEMPERATURE
#if defined(SKIP_M109_IF_WITHIN) && SKIP_M109_IF_WITHIN > 0
&& !(abs(tc->currentTemperatureC - tc->targetTemperatureC) < (SKIP_M109_IF_WITHIN))// Already in range
#endif
)
{
Extruder *actExtruder = &extruder[extr];
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UI_STATUS_UPD_F(Com::translatedF(UI_TEXT_HEATING_EXTRUDER_ID));
EVENT_WAITING_HEATER(actExtruder->id);
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bool dirRising = actExtruder->tempControl.targetTemperatureC > actExtruder->tempControl.currentTemperatureC;
millis_t printedTime = HAL::timeInMilliseconds();
millis_t waituntil = 0;
#if RETRACT_DURING_HEATUP
uint8_t retracted = 0;
#endif
millis_t currentTime;
do
{
previousMillisCmd = currentTime = HAL::timeInMilliseconds();
if( (currentTime - printedTime) > 1000 ) //Print Temp Reading every 1 second while heating up.
{
Commands::printTemperatures();
printedTime = currentTime;
}
Commands::checkForPeriodicalActions(true);
//gcode_read_serial();
#if RETRACT_DURING_HEATUP
if (actExtruder == Extruder::current && actExtruder->waitRetractUnits > 0 && !retracted && dirRising && actExtruder->tempControl.currentTemperatureC > actExtruder->waitRetractTemperature)
{
PrintLine::moveRelativeDistanceInSteps(0, 0, 0, -actExtruder->waitRetractUnits * Printer::axisStepsPerMM[E_AXIS], actExtruder->maxFeedrate / 4, false, false);
retracted = 1;
}
#endif
if((waituntil == 0 &&
(dirRising ? actExtruder->tempControl.currentTemperatureC >= actExtruder->tempControl.targetTemperatureC - 1
: actExtruder->tempControl.currentTemperatureC <= actExtruder->tempControl.targetTemperatureC + 1))
#if defined(TEMP_HYSTERESIS) && TEMP_HYSTERESIS>=1
|| (waituntil != 0 && (abs(actExtruder->tempControl.currentTemperatureC - actExtruder->tempControl.targetTemperatureC)) > TEMP_HYSTERESIS)
#endif
)
{
waituntil = currentTime + 1000UL*(millis_t)actExtruder->watchPeriod; // now wait for temp. to stabalize
}
}
while(waituntil == 0 || (waituntil != 0 && (millis_t)(waituntil - currentTime) < 2000000000UL));
#if RETRACT_DURING_HEATUP
if (retracted && actExtruder == Extruder::current)
{
PrintLine::moveRelativeDistanceInSteps(0, 0, 0, actExtruder->waitRetractUnits * Printer::axisStepsPerMM[E_AXIS], actExtruder->maxFeedrate / 4, false, false);
}
#endif
EVENT_HEATING_FINISHED(actExtruder->id);
}
UI_CLEAR_STATUS;
bool alloff = true;
for(uint8_t i = 0; i < NUM_EXTRUDER; i++)
if(tempController[i]->targetTemperatureC > 15) alloff = false;
#if EEPROM_MODE != 0
if(alloff && !alloffs) // All heaters are now switched off?
EEPROM::updatePrinterUsage();
#endif
if(alloffs && !alloff) // heaters are turned on, start measuring printing time
{
Printer::msecondsPrinting = HAL::timeInMilliseconds();
Printer::filamentPrinted = 0; // new print, new counter
Printer::flag2 &= ~PRINTER_FLAG2_RESET_FILAMENT_USAGE;
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}
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#endif
}
void Extruder::setHeatedBedTemperature(float temperatureInCelsius,bool beep)
{
#if HAVE_HEATED_BED
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if(temperatureInCelsius > HEATED_BED_MAX_TEMP) temperatureInCelsius = HEATED_BED_MAX_TEMP;
if(temperatureInCelsius < 0) temperatureInCelsius = 0;
if(heatedBedController.targetTemperatureC==temperatureInCelsius) return; // don't flood log with messages if killed
heatedBedController.setTargetTemperature(temperatureInCelsius);
if(beep && temperatureInCelsius>30) heatedBedController.setAlarm(true);
Com::printFLN(Com::tTargetBedColon,heatedBedController.targetTemperatureC,0);
if(temperatureInCelsius > 15)
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pwm_pos[PWM_BOARD_FAN] = BOARD_FAN_SPEED; // turn on the mainboard cooling fan
else if(Printer::areAllSteppersDisabled())
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pwm_pos[PWM_BOARD_FAN] = 0; // turn off the mainboard cooling fan only if steppers disabled
#endif
}
float Extruder::getHeatedBedTemperature()
{
#if HAVE_HEATED_BED
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TemperatureController *c = tempController[HEATED_BED_INDEX];
return c->currentTemperatureC;
#else
return -1;
#endif
}
#if MIXING_EXTRUDER > 0
void Extruder::setMixingWeight(uint8_t extr,int weight)
{
uint8_t i;
mixingS = 0;
extruder[extr].mixingW = weight;
for(i=0; i<NUM_EXTRUDER; i++)
{
extruder[i].mixingE = extruder[i].mixingW;
mixingS += extruder[i].mixingW;
}
}
void Extruder::step()
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{
if(PrintLine::cur != NULL && PrintLine::cur->isAllEMotors()) {
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#if NUM_EXTRUDER > 0
WRITE(EXT0_STEP_PIN, START_STEP_WITH_HIGH);
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#if defined(EXT0_MIRROR_STEPPER) && EXT0_MIRROR_STEPPER
WRITE(EXT0_STEP2_PIN, START_STEP_WITH_HIGH);
#endif
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#if EXTRUDER_JAM_CONTROL && defined(EXT0_JAM_PIN) && EXT0_JAM_PIN > -1
TEST_EXTRUDER_JAM(0)
#endif
#endif
#if NUM_EXTRUDER > 1
WRITE(EXT1_STEP_PIN, START_STEP_WITH_HIGH);
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#if defined(EXT1_MIRROR_STEPPER) && EXT1_MIRROR_STEPPER
WRITE(EXT1_STEP2_PIN, START_STEP_WITH_HIGH);
#endif
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#if EXTRUDER_JAM_CONTROL && defined(EXT1_JAM_PIN) && EXT1_JAM_PIN > -1
TEST_EXTRUDER_JAM(1)
#endif
#endif
#if NUM_EXTRUDER > 2
WRITE(EXT2_STEP_PIN, START_STEP_WITH_HIGH);
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#if defined(EXT2_MIRROR_STEPPER) && EXT2_MIRROR_STEPPER
WRITE(EXT2_STEP2_PIN, START_STEP_WITH_HIGH);
#endif
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#if EXTRUDER_JAM_CONTROL && defined(EXT2_JAM_PIN) && EXT2_JAM_PIN > -1
TEST_EXTRUDER_JAM(2)
#endif
#endif
#if NUM_EXTRUDER > 3
WRITE(EXT3_STEP_PIN, START_STEP_WITH_HIGH);
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#if defined(EXT3_MIRROR_STEPPER) && EXT3_MIRROR_STEPPER
WRITE(EXT3_STEP2_PIN, START_STEP_WITH_HIGH);
#endif
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#if EXTRUDER_JAM_CONTROL && defined(EXT3_JAM_PIN) && EXT3_JAM_PIN > -1
TEST_EXTRUDER_JAM(3)
#endif
#endif
#if NUM_EXTRUDER > 4
WRITE(EXT4_STEP_PIN, START_STEP_WITH_HIGH);
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#if defined(EXT4_MIRROR_STEPPER) && EXT4_MIRROR_STEPPER
WRITE(EXT4_STEP2_PIN, START_STEP_WITH_HIGH);
#endif
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#if EXTRUDER_JAM_CONTROL && defined(EXT4_JAM_PIN) && EXT4_JAM_PIN > -1
TEST_EXTRUDER_JAM(4)
#endif
#endif
#if NUM_EXTRUDER > 5
WRITE(EXT5_STEP_PIN, START_STEP_WITH_HIGH);
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#if defined(EXT5_MIRROR_STEPPER) && EXT5_MIRROR_STEPPER
WRITE(EXT5_STEP2_PIN, START_STEP_WITH_HIGH);
#endif
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#if EXTRUDER_JAM_CONTROL && defined(EXT5_JAM_PIN) && EXT5_JAM_PIN > -1
TEST_EXTRUDER_JAM(5)
#endif
#endif
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return;
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}
uint8_t best = 255,i;
int bestError;
if(mixingDir)
{
bestError = -10000;
for(i = 0; i < NUM_EXTRUDER; i++)
{
if(extruder[i].mixingW == 0) continue;
if(extruder[i].mixingE > bestError)
{
bestError = extruder[i].mixingE;
best = i;
}
extruder[i].mixingE += extruder[i].mixingW;
}
if(best == 255) return; // no extruder has weight!
extruder[best].mixingE -= mixingS;
}
else
{
bestError = 10000;
for(i = 0; i < NUM_EXTRUDER; i++)
{
if(extruder[i].mixingW == 0) continue;
if(extruder[i].mixingE < bestError)
{
bestError = extruder[i].mixingE;
best = i;
}
extruder[i].mixingE -= extruder[i].mixingW;
}
if(best == 255) return; // no extruder has weight!
extruder[best].mixingE += mixingS;
}
#if NUM_EXTRUDER > 0
if(best == 0)
{
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WRITE(EXT0_STEP_PIN, START_STEP_WITH_HIGH);
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#if defined(EXT0_MIRROR_STEPPER) && EXT0_MIRROR_STEPPER
WRITE(EXT0_STEP2_PIN, START_STEP_WITH_HIGH);
#endif
#if EXTRUDER_JAM_CONTROL && defined(EXT0_JAM_PIN) && EXT0_JAM_PIN > -1
TEST_EXTRUDER_JAM(0)
#endif
}
#endif
#if NUM_EXTRUDER > 1
if(best == 1)
{
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WRITE(EXT1_STEP_PIN, START_STEP_WITH_HIGH);
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#if defined(EXT1_MIRROR_STEPPER) && EXT1_MIRROR_STEPPER
WRITE(EXT1_STEP2_PIN, START_STEP_WITH_HIGH);
#endif
#if EXTRUDER_JAM_CONTROL && defined(EXT1_JAM_PIN) && EXT1_JAM_PIN > -1
TEST_EXTRUDER_JAM(1)
#endif
}
#endif
#if NUM_EXTRUDER > 2
if(best == 2)
{
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WRITE(EXT2_STEP_PIN, START_STEP_WITH_HIGH);
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#if defined(EXT2_MIRROR_STEPPER) && EXT2_MIRROR_STEPPER
WRITE(EXT2_STEP2_PIN, START_STEP_WITH_HIGH);
#endif
#if EXTRUDER_JAM_CONTROL && defined(EXT2_JAM_PIN) && EXT2_JAM_PIN > -1
TEST_EXTRUDER_JAM(2)
#endif
}
#endif
#if NUM_EXTRUDER > 3
if(best == 3)
{
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WRITE(EXT3_STEP_PIN, START_STEP_WITH_HIGH);
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#if defined(EXT3_MIRROR_STEPPER) && EXT3_MIRROR_STEPPER
WRITE(EXT3_STEP2_PIN, START_STEP_WITH_HIGH);
#endif
#if EXTRUDER_JAM_CONTROL && defined(EXT3_JAM_PIN) && EXT3_JAM_PIN > -1
TEST_EXTRUDER_JAM(3)
#endif
}
#endif
#if NUM_EXTRUDER > 4
if(best == 4)
{
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WRITE(EXT4_STEP_PIN, START_STEP_WITH_HIGH);
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#if defined(EXT4_MIRROR_STEPPER) && EXT4_MIRROR_STEPPER
WRITE(EXT4_STEP2_PIN, START_STEP_WITH_HIGH);
#endif
#if EXTRUDER_JAM_CONTROL && defined(EXT4_JAM_PIN) && EXT4_JAM_PIN > -1
TEST_EXTRUDER_JAM(4)
#endif
}
#endif
#if NUM_EXTRUDER > 5
if(best == 5)
{
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WRITE(EXT5_STEP_PIN, START_STEP_WITH_HIGH);
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#if defined(EXT5_MIRROR_STEPPER) && EXT5_MIRROR_STEPPER
WRITE(EXT5_STEP2_PIN, START_STEP_WITH_HIGH);
#endif
#if EXTRUDER_JAM_CONTROL && defined(EXT5_JAM_PIN) && EXT5_JAM_PIN > -1
TEST_EXTRUDER_JAM(5)
#endif
}
#endif
}
void Extruder::unstep()
{
#if NUM_EXTRUDER > 0
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WRITE(EXT0_STEP_PIN, !START_STEP_WITH_HIGH);
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#if defined(EXT0_MIRROR_STEPPER) && EXT0_MIRROR_STEPPER
WRITE(EXT0_STEP2_PIN, !START_STEP_WITH_HIGH);
#endif
#endif
#if NUM_EXTRUDER > 1
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WRITE(EXT1_STEP_PIN, !START_STEP_WITH_HIGH);
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#if defined(EXT1_MIRROR_STEPPER) && EXT1_MIRROR_STEPPER
WRITE(EXT1_STEP2_PIN, !START_STEP_WITH_HIGH);
#endif
#endif
#if NUM_EXTRUDER > 2
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WRITE(EXT2_STEP_PIN, !START_STEP_WITH_HIGH);
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#if defined(EXT2_MIRROR_STEPPER) && EXT2_MIRROR_STEPPER
WRITE(EXT2_STEP2_PIN, !START_STEP_WITH_HIGH);
#endif
#endif
#if NUM_EXTRUDER > 3
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WRITE(EXT3_STEP_PIN, !START_STEP_WITH_HIGH);
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#if defined(EXT3_MIRROR_STEPPER) && EXT3_MIRROR_STEPPER
WRITE(EXT3_STEP2_PIN, !START_STEP_WITH_HIGH);
#endif
#endif
#if NUM_EXTRUDER > 4
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WRITE(EXT4_STEP_PIN, !START_STEP_WITH_HIGH);
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#if defined(EXT4_MIRROR_STEPPER) && EXT4_MIRROR_STEPPER
WRITE(EXT4_STEP2_PIN, !START_STEP_WITH_HIGH);
#endif
#endif
#if NUM_EXTRUDER > 5
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WRITE(EXT5_STEP_PIN, !START_STEP_WITH_HIGH);
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#if defined(EXT5_MIRROR_STEPPER) && EXT5_MIRROR_STEPPER
WRITE(EXT5_STEP2_PIN, !START_STEP_WITH_HIGH);
#endif
#endif
}
void Extruder::setDirection(uint8_t dir)
{
mixingDir = dir;
#if NUM_EXTRUDER > 0
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if(dir) {
WRITE(EXT0_DIR_PIN,!EXT0_INVERSE);
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#if defined(EXT0_MIRROR_STEPPER) && EXT0_MIRROR_STEPPER
WRITE(EXT0_DIR2_PIN, !EXT0_INVERSE2);
#endif
} else {
WRITE(EXT0_DIR_PIN,EXT0_INVERSE);
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#if defined(EXT0_MIRROR_STEPPER) && EXT0_MIRROR_STEPPER
WRITE(EXT0_DIR2_PIN, EXT0_INVERSE2);
#endif
}
RESET_EXTRUDER_JAM(0, dir)
#endif
#if defined(EXT1_DIR_PIN) && NUM_EXTRUDER > 1
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if(dir) {
WRITE(EXT1_DIR_PIN,!EXT1_INVERSE);
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#if defined(EXT1_MIRROR_STEPPER) && EXT1_MIRROR_STEPPER
WRITE(EXT1_DIR2_PIN, !EXT1_INVERSE2);
#endif
} else {
WRITE(EXT1_DIR_PIN,EXT1_INVERSE);
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#if defined(EXT1_MIRROR_STEPPER) && EXT1_MIRROR_STEPPER
WRITE(EXT1_DIR2_PIN, EXT1_INVERSE2);
#endif
}
RESET_EXTRUDER_JAM(1, dir)
#endif
#if defined(EXT2_DIR_PIN) && NUM_EXTRUDER > 2
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if(dir) {
WRITE(EXT2_DIR_PIN,!EXT2_INVERSE);
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#if defined(EXT2_MIRROR_STEPPER) && EXT2_MIRROR_STEPPER
WRITE(EXT2_DIR2_PIN, !EXT2_INVERSE2);
#endif
} else {
WRITE(EXT2_DIR_PIN,EXT2_INVERSE);
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#if defined(EXT2_MIRROR_STEPPER) && EXT2_MIRROR_STEPPER
WRITE(EXT2_DIR2_PIN, EXT2_INVERSE2);
#endif
}
RESET_EXTRUDER_JAM(2, dir)
#endif
#if defined(EXT3_DIR_PIN) && NUM_EXTRUDER > 3
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if(dir) {
WRITE(EXT3_DIR_PIN,!EXT3_INVERSE);
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#if defined(EXT3_MIRROR_STEPPER) && EXT3_MIRROR_STEPPER
WRITE(EXT3_DIR2_PIN, !EXT3_INVERSE2);
#endif
} else {
WRITE(EXT3_DIR_PIN,EXT3_INVERSE);
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#if defined(EXT3_MIRROR_STEPPER) && EXT3_MIRROR_STEPPER
WRITE(EXT3_DIR2_PIN, EXT3_INVERSE2);
#endif
}
RESET_EXTRUDER_JAM(3, dir)
#endif
#if defined(EXT4_DIR_PIN) && NUM_EXTRUDER > 4
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if(dir) {
WRITE(EXT4_DIR_PIN,!EXT4_INVERSE);
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#if defined(EXT4_MIRROR_STEPPER) && EXT4_MIRROR_STEPPER
WRITE(EXT4_DIR2_PIN, !EXT4_INVERSE2);
#endif
} else {
WRITE(EXT4_DIR_PIN,EXT4_INVERSE);
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#if defined(EXT4_MIRROR_STEPPER) && EXT4_MIRROR_STEPPER
WRITE(EXT4_DIR2_PIN, EXT4_INVERSE2);
#endif
}
RESET_EXTRUDER_JAM(4, dir)
#endif
#if defined(EXT5_DIR_PIN) && NUM_EXTRUDER > 5
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if(dir) {
WRITE(EXT5_DIR_PIN,!EXT5_INVERSE);
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#if defined(EXT5_MIRROR_STEPPER) && EXT5_MIRROR_STEPPER
WRITE(EXT5_DIR2_PIN, !EXT5_INVERSE2);
#endif
} else {
WRITE(EXT5_DIR_PIN,EXT5_INVERSE);
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#if defined(EXT5_MIRROR_STEPPER) && EXT5_MIRROR_STEPPER
WRITE(EXT5_DIR2_PIN, EXT5_INVERSE2);
#endif
}
RESET_EXTRUDER_JAM(5, dir)
#endif
}
void Extruder::enable()
{
#if NUM_EXTRUDER > 0 && defined(EXT0_ENABLE_PIN) && EXT0_ENABLE_PIN > -1
WRITE(EXT0_ENABLE_PIN, EXT0_ENABLE_ON );
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#if defined(EXT0_MIRROR_STEPPER) && EXT0_MIRROR_STEPPER
WRITE(EXT0_ENABLE2_PIN, EXT0_ENABLE_ON);
#endif
#endif
#if NUM_EXTRUDER > 1 && defined(EXT1_ENABLE_PIN) && EXT1_ENABLE_PIN > -1
WRITE(EXT1_ENABLE_PIN, EXT1_ENABLE_ON );
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#if defined(EXT1_MIRROR_STEPPER) && EXT1_MIRROR_STEPPER
WRITE(EX10_ENABLE2_PIN, EXT1_ENABLE_ON);
#endif
#endif
#if NUM_EXTRUDER > 2 && defined(EXT2_ENABLE_PIN) && EXT2_ENABLE_PIN > -1
WRITE(EXT2_ENABLE_PIN, EXT2_ENABLE_ON );
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#if defined(EXT2_MIRROR_STEPPER) && EXT2_MIRROR_STEPPER
WRITE(EXT2_ENABLE2_PIN, EXT2_ENABLE_ON);
#endif
#endif
#if NUM_EXTRUDER > 3 && defined(EXT3_ENABLE_PIN) && EXT3_ENABLE_PIN > -1
WRITE(EXT3_ENABLE_PIN, EXT3_ENABLE_ON );
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#if defined(EXT3_MIRROR_STEPPER) && EXT3_MIRROR_STEPPER
WRITE(EXT3_ENABLE2_PIN, EXT3_ENABLE_ON);
#endif
#endif
#if NUM_EXTRUDER > 4 && defined(EXT4_ENABLE_PIN) && EXT4_ENABLE_PIN > -1
WRITE(EXT4_ENABLE_PIN, EXT4_ENABLE_ON );
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#if defined(EXT4_MIRROR_STEPPER) && EXT4_MIRROR_STEPPER
WRITE(EXT4_ENABLE2_PIN, EXT4_ENABLE_ON);
#endif
#endif
#if NUM_EXTRUDER > 5 && defined(EXT5_ENABLE_PIN) && EXT5_ENABLE_PIN > -1
WRITE(EXT5_ENABLE_PIN, EXT5_ENABLE_ON );
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#if defined(EXT5_MIRROR_STEPPER) && EXT5_MIRROR_STEPPER
WRITE(EXT5_ENABLE2_PIN, EXT5_ENABLE_ON);
#endif
#endif
}
#else // Normal extruder
/** \brief Sends the high-signal to the stepper for next extruder step.
Call this function only, if interrupts are disabled.
*/
void Extruder::step()
{
#if NUM_EXTRUDER == 1
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WRITE(EXT0_STEP_PIN, START_STEP_WITH_HIGH);
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#if defined(EXT0_MIRROR_STEPPER) && EXT0_MIRROR_STEPPER
WRITE(EXT0_STEP2_PIN, START_STEP_WITH_HIGH);
#endif
#if EXTRUDER_JAM_CONTROL && defined(EXT0_JAM_PIN) && EXT0_JAM_PIN > -1
TEST_EXTRUDER_JAM(0)
#endif
#else
switch(Extruder::current->id)
{
case 0:
#if NUM_EXTRUDER > 0
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WRITE(EXT0_STEP_PIN,START_STEP_WITH_HIGH);
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#if defined(EXT0_MIRROR_STEPPER) && EXT0_MIRROR_STEPPER
WRITE(EXT0_STEP2_PIN, START_STEP_WITH_HIGH);
#endif
#if EXTRUDER_JAM_CONTROL && defined(EXT0_JAM_PIN) && EXT0_JAM_PIN > -1
TEST_EXTRUDER_JAM(0)
#endif
#if FEATURE_DITTO_PRINTING
if(Extruder::dittoMode)
{
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WRITE(EXT1_STEP_PIN,START_STEP_WITH_HIGH);
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#if defined(EXT1_MIRROR_STEPPER) && EXT1_MIRROR_STEPPER
WRITE(EXT1_STEP2_PIN, START_STEP_WITH_HIGH);
#endif
#if EXTRUDER_JAM_CONTROL && defined(EXT1_JAM_PIN) && EXT1_JAM_PIN > -1
TEST_EXTRUDER_JAM(1)
#endif
#if NUM_EXTRUDER > 2
if(Extruder::dittoMode > 1)
{
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WRITE(EXT2_STEP_PIN,START_STEP_WITH_HIGH);
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#if defined(EXT2_MIRROR_STEPPER) && EXT2_MIRROR_STEPPER
WRITE(EXT2_STEP2_PIN, START_STEP_WITH_HIGH);
#endif
#if EXTRUDER_JAM_CONTROL && defined(EXT2_JAM_PIN) && EXT2_JAM_PIN > -1
TEST_EXTRUDER_JAM(2)
#endif
}
#endif
#if NUM_EXTRUDER > 3
if(Extruder::dittoMode > 2)
{
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WRITE(EXT3_STEP_PIN,START_STEP_WITH_HIGH);
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#if defined(EXT3_MIRROR_STEPPER) && EXT3_MIRROR_STEPPER
WRITE(EXT3_STEP2_PIN, START_STEP_WITH_HIGH);
#endif
#if EXTRUDER_JAM_CONTROL && defined(EXT3_JAM_PIN) && EXT3_JAM_PIN > -1
TEST_EXTRUDER_JAM(3)
#endif
}
#endif
}
#endif
#endif
break;
#if defined(EXT1_STEP_PIN) && NUM_EXTRUDER > 1
case 1:
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WRITE(EXT1_STEP_PIN,START_STEP_WITH_HIGH);
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#if defined(EXT1_MIRROR_STEPPER) && EXT1_MIRROR_STEPPER
WRITE(EXT1_STEP2_PIN, START_STEP_WITH_HIGH);
#endif
#if EXTRUDER_JAM_CONTROL && defined(EXT1_JAM_PIN) && EXT1_JAM_PIN > -1
TEST_EXTRUDER_JAM(1)
#endif
break;
#endif
#if defined(EXT2_STEP_PIN) && NUM_EXTRUDER > 2
case 2:
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WRITE(EXT2_STEP_PIN,START_STEP_WITH_HIGH);
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#if defined(EXT2_MIRROR_STEPPER) && EXT2_MIRROR_STEPPER
WRITE(EXT2_STEP2_PIN, START_STEP_WITH_HIGH);
#endif
#if EXTRUDER_JAM_CONTROL && defined(EXT2_JAM_PIN) && EXT2_JAM_PIN > -1
TEST_EXTRUDER_JAM(2)
#endif
break;
#endif
#if defined(EXT3_STEP_PIN) && NUM_EXTRUDER > 3
case 3:
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WRITE(EXT3_STEP_PIN,START_STEP_WITH_HIGH);
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#if defined(EXT3_MIRROR_STEPPER) && EXT3_MIRROR_STEPPER
WRITE(EXT3_STEP2_PIN, START_STEP_WITH_HIGH);
#endif
#if EXTRUDER_JAM_CONTROL && defined(EXT3_JAM_PIN) && EXT3_JAM_PIN > -1
TEST_EXTRUDER_JAM(3)
#endif
break;
#endif
#if defined(EXT4_STEP_PIN) && NUM_EXTRUDER > 4
case 4:
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WRITE(EXT4_STEP_PIN,START_STEP_WITH_HIGH);
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#if defined(EXT4_MIRROR_STEPPER) && EXT4_MIRROR_STEPPER
WRITE(EXT4_STEP2_PIN, START_STEP_WITH_HIGH);
#endif
#if EXTRUDER_JAM_CONTROL && defined(EXT4_JAM_PIN) && EXT4_JAM_PIN > -1
TEST_EXTRUDER_JAM(4)
#endif
break;
#endif
#if defined(EXT5_STEP_PIN) && NUM_EXTRUDER > 5
case 5:
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WRITE(EXT5_STEP_PIN,START_STEP_WITH_HIGH);
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#if defined(EXT5_MIRROR_STEPPER) && EXT5_MIRROR_STEPPER
WRITE(EXT5_STEP2_PIN, START_STEP_WITH_HIGH);
#endif
#if EXTRUDER_JAM_CONTROL && defined(EXT5_JAM_PIN) && EXT5_JAM_PIN > -1
TEST_EXTRUDER_JAM(5)
#endif
break;
#endif
}
#endif
}
/** \brief Sets stepper signal to low for current extruder.
Call this function only, if interrupts are disabled.
*/
void Extruder::unstep()
{
#if NUM_EXTRUDER == 1
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WRITE(EXT0_STEP_PIN,!START_STEP_WITH_HIGH);
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#if defined(EXT0_MIRROR_STEPPER) && EXT0_MIRROR_STEPPER
WRITE(EXT0_STEP2_PIN, !START_STEP_WITH_HIGH);
#endif
#else
switch(Extruder::current->id)
{
case 0:
#if NUM_EXTRUDER > 0
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WRITE(EXT0_STEP_PIN,!START_STEP_WITH_HIGH);
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#if defined(EXT0_MIRROR_STEPPER) && EXT0_MIRROR_STEPPER
WRITE(EXT0_STEP2_PIN, !START_STEP_WITH_HIGH);
#endif
#if FEATURE_DITTO_PRINTING
if(Extruder::dittoMode)
{
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WRITE(EXT1_STEP_PIN,!START_STEP_WITH_HIGH);
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#if defined(EXT1_MIRROR_STEPPER) && EXT1_MIRROR_STEPPER
WRITE(EXT1_STEP2_PIN, !START_STEP_WITH_HIGH);
#endif
#if NUM_EXTRUDER > 2
if(Extruder::dittoMode > 1)
{
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WRITE(EXT2_STEP_PIN,!START_STEP_WITH_HIGH);
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#if defined(EXT2_MIRROR_STEPPER) && EXT2_MIRROR_STEPPER
WRITE(EXT2_STEP2_PIN, !START_STEP_WITH_HIGH);
#endif
}
#endif
#if NUM_EXTRUDER > 3
if(Extruder::dittoMode > 2)
{
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WRITE(EXT3_STEP_PIN,!START_STEP_WITH_HIGH);
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#if defined(EXT3_MIRROR_STEPPER) && EXT3_MIRROR_STEPPER
WRITE(EXT3_STEP2_PIN, !START_STEP_WITH_HIGH);
#endif
}
#endif // NUM_EXTRUDER > 3
}
#endif // FEATURE_DITTO_PRINTING
#endif // NUM_EXTRUDER > 0
break;
#if defined(EXT1_STEP_PIN) && NUM_EXTRUDER > 1
case 1:
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WRITE(EXT1_STEP_PIN,!START_STEP_WITH_HIGH);
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#if defined(EXT1_MIRROR_STEPPER) && EXT1_MIRROR_STEPPER
WRITE(EXT1_STEP2_PIN, !START_STEP_WITH_HIGH);
#endif
break;
#endif
#if defined(EXT2_STEP_PIN) && NUM_EXTRUDER > 2
case 2:
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WRITE(EXT2_STEP_PIN,!START_STEP_WITH_HIGH);
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#if defined(EXT2_MIRROR_STEPPER) && EXT2_MIRROR_STEPPER
WRITE(EXT2_STEP2_PIN, !START_STEP_WITH_HIGH);
#endif
break;
#endif
#if defined(EXT3_STEP_PIN) && NUM_EXTRUDER > 3
case 3:
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WRITE(EXT3_STEP_PIN,!START_STEP_WITH_HIGH);
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#if defined(EXT3_MIRROR_STEPPER) && EXT3_MIRROR_STEPPER
WRITE(EXT3_STEP2_PIN, !START_STEP_WITH_HIGH);
#endif
break;
#endif
#if defined(EXT4_STEP_PIN) && NUM_EXTRUDER > 4
case 4:
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WRITE(EXT4_STEP_PIN,!START_STEP_WITH_HIGH);
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#if defined(EXT4_MIRROR_STEPPER) && EXT4_MIRROR_STEPPER
WRITE(EXT4_STEP2_PIN, !START_STEP_WITH_HIGH);
#endif
break;
#endif
#if defined(EXT5_STEP_PIN) && NUM_EXTRUDER > 5
case 5:
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WRITE(EXT5_STEP_PIN,!START_STEP_WITH_HIGH);
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#if defined(EXT5_MIRROR_STEPPER) && EXT5_MIRROR_STEPPER
WRITE(EXT5_STEP2_PIN, !START_STEP_WITH_HIGH);
#endif
break;
#endif
}
#endif
}
/** \brief Activates the extruder stepper and sets the direction. */
void Extruder::setDirection(uint8_t dir)
{
#if NUM_EXTRUDER == 1
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if(dir) {
WRITE(EXT0_DIR_PIN, !EXT0_INVERSE);
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#if defined(EXT0_MIRROR_STEPPER) && EXT0_MIRROR_STEPPER
WRITE(EXT0_DIR2_PIN, !EXT0_INVERSE2);
#endif
} else {
WRITE(EXT0_DIR_PIN, EXT0_INVERSE);
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#if defined(EXT0_MIRROR_STEPPER) && EXT0_MIRROR_STEPPER
WRITE(EXT0_DIR2_PIN, EXT0_INVERSE2);
#endif
}
RESET_EXTRUDER_JAM(0, dir)
#else
switch(Extruder::current->id)
{
#if NUM_EXTRUDER > 0
case 0:
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if(dir) {
WRITE(EXT0_DIR_PIN,!EXT0_INVERSE);
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#if defined(EXT0_MIRROR_STEPPER) && EXT0_MIRROR_STEPPER
WRITE(EXT0_DIR2_PIN, !EXT0_INVERSE2);
#endif
} else {
WRITE(EXT0_DIR_PIN,EXT0_INVERSE);
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#if defined(EXT0_MIRROR_STEPPER) && EXT0_MIRROR_STEPPER
WRITE(EXT0_DIR2_PIN, EXT0_INVERSE2);
#endif
}
RESET_EXTRUDER_JAM(0, dir)
#if FEATURE_DITTO_PRINTING
if(Extruder::dittoMode)
{
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if(dir) {
WRITE(EXT1_DIR_PIN,!EXT1_INVERSE);
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#if defined(EXT1_MIRROR_STEPPER) && EXT1_MIRROR_STEPPER
WRITE(EXT1_DIR2_PIN, !EXT1_INVERSE2);
#endif
} else {
WRITE(EXT1_DIR_PIN,EXT1_INVERSE);
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#if defined(EXT1_MIRROR_STEPPER) && EXT1_MIRROR_STEPPER
WRITE(EXT1_DIR2_PIN, EXT1_INVERSE2);
#endif
}
RESET_EXTRUDER_JAM(1, dir)
#if NUM_EXTRUDER > 2
if(Extruder::dittoMode > 1)
{
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if(dir) {
WRITE(EXT2_DIR_PIN,!EXT2_INVERSE);
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#if defined(EXT2_MIRROR_STEPPER) && EXT2_MIRROR_STEPPER
WRITE(EXT2_DIR2_PIN, !EXT2_INVERSE2);
#endif
} else {
WRITE(EXT2_DIR_PIN,EXT2_INVERSE);
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#if defined(EXT2_MIRROR_STEPPER) && EXT2_MIRROR_STEPPER
WRITE(EXT2_DIR2_PIN, EXT2_INVERSE2);
#endif
}
RESET_EXTRUDER_JAM(2, dir)
}
#endif
#if NUM_EXTRUDER > 3
if(Extruder::dittoMode > 2)
{
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if(dir) {
WRITE(EXT3_DIR_PIN,!EXT3_INVERSE);
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#if defined(EXT3_MIRROR_STEPPER) && EXT3_MIRROR_STEPPER
WRITE(EXT3_DIR2_PIN, !EXT3_INVERSE2);
#endif
} else {
WRITE(EXT3_DIR_PIN,EXT3_INVERSE);
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#if defined(EXT3_MIRROR_STEPPER) && EXT3_MIRROR_STEPPER
WRITE(EXT3_DIR2_PIN, EXT3_INVERSE2);
#endif
}
RESET_EXTRUDER_JAM(3, dir)
}
#endif
}
#endif
break;
#endif
#if defined(EXT1_DIR_PIN) && NUM_EXTRUDER > 1
case 1:
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if(dir) {
WRITE(EXT1_DIR_PIN,!EXT1_INVERSE);
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#if defined(EXT1_MIRROR_STEPPER) && EXT1_MIRROR_STEPPER
WRITE(EXT1_DIR2_PIN, !EXT1_INVERSE2);
#endif
} else {
WRITE(EXT1_DIR_PIN,EXT1_INVERSE);
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#if defined(EXT1_MIRROR_STEPPER) && EXT1_MIRROR_STEPPER
WRITE(EXT1_DIR2_PIN, EXT1_INVERSE2);
#endif
}
RESET_EXTRUDER_JAM(1, dir)
break;
#endif
#if defined(EXT2_DIR_PIN) && NUM_EXTRUDER > 2
case 2:
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if(dir) {
WRITE(EXT2_DIR_PIN,!EXT2_INVERSE);
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#if defined(EXT2_MIRROR_STEPPER) && EXT2_MIRROR_STEPPER
WRITE(EXT2_DIR2_PIN, !EXT2_INVERSE2);
#endif
} else {
WRITE(EXT2_DIR_PIN,EXT2_INVERSE);
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#if defined(EXT2_MIRROR_STEPPER) && EXT2_MIRROR_STEPPER
WRITE(EXT2_DIR2_PIN, EXT2_INVERSE2);
#endif
}
RESET_EXTRUDER_JAM(2, dir)
break;
#endif
#if defined(EXT3_DIR_PIN) && NUM_EXTRUDER > 3
case 3:
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if(dir) {
WRITE(EXT3_DIR_PIN,!EXT3_INVERSE);
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#if defined(EXT3_MIRROR_STEPPER) && EXT3_MIRROR_STEPPER
WRITE(EXT3_DIR2_PIN, !EXT3_INVERSE2);
#endif
} else {
WRITE(EXT3_DIR_PIN,EXT3_INVERSE);
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#if defined(EXT3_MIRROR_STEPPER) && EXT3_MIRROR_STEPPER
WRITE(EXT3_DIR2_PIN, EXT3_INVERSE2);
#endif
}
RESET_EXTRUDER_JAM(3, dir)
break;
#endif
#if defined(EXT4_DIR_PIN) && NUM_EXTRUDER > 4
case 4:
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if(dir) {
WRITE(EXT4_DIR_PIN,!EXT4_INVERSE);
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#if defined(EXT4_MIRROR_STEPPER) && EXT4_MIRROR_STEPPER
WRITE(EXT4_DIR2_PIN, !EXT4_INVERSE2);
#endif
} else {
WRITE(EXT4_DIR_PIN,EXT4_INVERSE);
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#if defined(EXT4_MIRROR_STEPPER) && EXT4_MIRROR_STEPPER
WRITE(EXT4_DIR2_PIN, EXT4_INVERSE2);
#endif
}
RESET_EXTRUDER_JAM(4, dir)
break;
#endif
#if defined(EXT5_DIR_PIN) && NUM_EXTRUDER > 5
case 5:
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if(dir) {
WRITE(EXT5_DIR_PIN,!EXT5_INVERSE);
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#if defined(EXT5_MIRROR_STEPPER) && EXT5_MIRROR_STEPPER
WRITE(EXT5_DIR2_PIN, !EXT5_INVERSE2);
#endif
} else {
WRITE(EXT5_DIR_PIN,EXT5_INVERSE);
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#if defined(EXT5_MIRROR_STEPPER) && EXT5_MIRROR_STEPPER
WRITE(EXT5_DIR2_PIN, EXT5_INVERSE2);
#endif
}
RESET_EXTRUDER_JAM(5, dir)
break;
#endif
}
#endif
}
void Extruder::enable()
{
#if NUM_EXTRUDER == 1
#if EXT0_ENABLE_PIN > -1
WRITE(EXT0_ENABLE_PIN,EXT0_ENABLE_ON );
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#if defined(EXT0_MIRROR_STEPPER) && EXT0_MIRROR_STEPPER
WRITE(EXT0_ENABLE2_PIN, EXT0_ENABLE_ON);
#endif
#endif
#else
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#if NUM_EXTRUDER > 0
switch(Extruder::current->id) {
#if defined(EXT0_MIRROR_STEPPER) && EXT0_MIRROR_STEPPER && NUM_EXTRUDER > 0
case 0:
WRITE(EXT0_ENABLE2_PIN, EXT0_ENABLE_ON);
break;
#endif
#if defined(EXT1_MIRROR_STEPPER) && EXT1_MIRROR_STEPPER && NUM_EXTRUDER > 1
case 1:
WRITE(EXT1_ENABLE2_PIN, EXT1_ENABLE_ON);
break;
#endif
#if defined(EXT2_MIRROR_STEPPER) && EXT2_MIRROR_STEPPER && NUM_EXTRUDER > 2
case 2:
WRITE(EXT2_ENABLE2_PIN, EXT2_ENABLE_ON);
break;
#endif
#if defined(EXT3_MIRROR_STEPPER) && EXT3_MIRROR_STEPPER && NUM_EXTRUDER > 3
case 3:
WRITE(EXT3_ENABLE2_PIN, EXT3_ENABLE_ON);
break;
#endif
#if defined(EXT4_MIRROR_STEPPER) && EXT4_MIRROR_STEPPER && NUM_EXTRUDER > 4
case 4:
WRITE(EXT4_ENABLE2_PIN, EXT4_ENABLE_ON);
break;
#endif
#if defined(EXT5_MIRROR_STEPPER) && EXT5_MIRROR_STEPPER && NUM_EXTRUDER > 5
case 5:
WRITE(EXT5_ENABLE2_PIN, EXT5_ENABLE_ON);
break;
#endif
}
if(Extruder::current->enablePin > -1)
digitalWrite(Extruder::current->enablePin,Extruder::current->enableOn);
#if FEATURE_DITTO_PRINTING
if(Extruder::dittoMode)
{
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if(extruder[1].enablePin > -1) {
digitalWrite(extruder[1].enablePin,extruder[1].enableOn);
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#if defined(EXT1_MIRROR_STEPPER) && EXT1_MIRROR_STEPPER && NUM_EXTRUDER > 1
WRITE(EXT1_ENABLE2_PIN, EXT1_ENABLE_ON);
#endif
}
#if NUM_EXTRUDER > 2
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if(Extruder::dittoMode > 1 && extruder[2].enablePin > -1) {
digitalWrite(extruder[2].enablePin,extruder[2].enableOn);
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#if defined(EXT2_MIRROR_STEPPER) && EXT2_MIRROR_STEPPER && NUM_EXTRUDER > 2
WRITE(EXT2_ENABLE2_PIN, EXT2_ENABLE_ON);
#endif
}
#endif
#if NUM_EXTRUDER > 3
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if(Extruder::dittoMode > 2 && extruder[3].enablePin > -1) {
digitalWrite(extruder[3].enablePin,extruder[3].enableOn);
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#if defined(EXT3_MIRROR_STEPPER) && EXT3_MIRROR_STEPPER && NUM_EXTRUDER > 3
WRITE(EXT3_ENABLE2_PIN, EXT3_ENABLE_ON);
#endif
}
#endif
}
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#endif
#endif
#endif
}
#endif // MIXING_EXTRUDER > 0
void Extruder::disableCurrentExtruderMotor()
{
#if MIXING_EXTRUDER
#if NUM_EXTRUDER > 0 && defined(EXT0_ENABLE_PIN) && EXT0_ENABLE_PIN > -1
WRITE(EXT0_ENABLE_PIN, !EXT0_ENABLE_ON );
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#if defined(EXT0_MIRROR_STEPPER) && EXT0_MIRROR_STEPPER
WRITE(EXT0_ENABLE2_PIN, !EXT0_ENABLE_ON);
#endif
#endif
#if NUM_EXTRUDER > 1 && defined(EXT1_ENABLE_PIN) && EXT1_ENABLE_PIN > -1
WRITE(EXT1_ENABLE_PIN, !EXT1_ENABLE_ON );
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#if defined(EXT1_MIRROR_STEPPER) && EXT1_MIRROR_STEPPER
WRITE(EXT1_ENABLE2_PIN, !EXT1_ENABLE_ON);
#endif
#endif
#if NUM_EXTRUDER > 2 && defined(EXT2_ENABLE_PIN) && EXT2_ENABLE_PIN > -1
WRITE(EXT2_ENABLE_PIN, !EXT2_ENABLE_ON );
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#if defined(EXT2_MIRROR_STEPPER) && EXT2_MIRROR_STEPPER
WRITE(EXT2_ENABLE2_PIN, !EXT2_ENABLE_ON);
#endif
#endif
#if NUM_EXTRUDER > 3 && defined(EXT3_ENABLE_PIN) && EXT3_ENABLE_PIN > -1
WRITE(EXT3_ENABLE_PIN, !EXT3_ENABLE_ON );
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#if defined(EXT3_MIRROR_STEPPER) && EXT3_MIRROR_STEPPER
WRITE(EXT3_ENABLE2_PIN, !EXT3_ENABLE_ON);
#endif
#endif
#if NUM_EXTRUDER > 4 && defined(EXT4_ENABLE_PIN) && EXT4_ENABLE_PIN > -1
WRITE(EXT4_ENABLE_PIN, !EXT4_ENABLE_ON );
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#if defined(EXT4_MIRROR_STEPPER) && EXT4_MIRROR_STEPPER
WRITE(EXT4_ENABLE2_PIN, !EXT4_ENABLE_ON);
#endif
#endif
#if NUM_EXTRUDER > 5 && defined(EXT5_ENABLE_PIN) && EXT5_ENABLE_PIN > -1
WRITE(EXT5_ENABLE_PIN, !EXT5_ENABLE_ON );
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#if defined(EXT5_MIRROR_STEPPER) && EXT5_MIRROR_STEPPER
WRITE(EXT5_ENABLE2_PIN, !EXT5_ENABLE_ON);
#endif
#endif
#else // MIXING_EXTRUDER
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#if NUM_EXTRUDER > 0
switch(Extruder::current->id) {
#if defined(EXT0_MIRROR_STEPPER) && EXT0_MIRROR_STEPPER && NUM_EXTRUDER > 0
case 0:
WRITE(EXT0_ENABLE2_PIN, !EXT0_ENABLE_ON);
break;
#endif
#if defined(EXT1_MIRROR_STEPPER) && EXT1_MIRROR_STEPPER && NUM_EXTRUDER > 1
case 1:
WRITE(EXT1_ENABLE2_PIN, !EXT1_ENABLE_ON);
break;
#endif
#if defined(EXT2_MIRROR_STEPPER) && EXT2_MIRROR_STEPPER && NUM_EXTRUDER > 2
case 2:
WRITE(EXT2_ENABLE2_PIN, !EXT2_ENABLE_ON);
break;
#endif
#if defined(EXT3_MIRROR_STEPPER) && EXT3_MIRROR_STEPPER && NUM_EXTRUDER > 3
case 3:
WRITE(EXT3_ENABLE2_PIN, !EXT3_ENABLE_ON);
break;
#endif
#if defined(EXT4_MIRROR_STEPPER) && EXT4_MIRROR_STEPPER && NUM_EXTRUDER > 4
case 4:
WRITE(EXT4_ENABLE2_PIN, !EXT4_ENABLE_ON);
break;
#endif
#if defined(EXT5_MIRROR_STEPPER) && EXT5_MIRROR_STEPPER && NUM_EXTRUDER > 5
case 5:
WRITE(EXT5_ENABLE2_PIN, !EXT5_ENABLE_ON);
break;
#endif
}
if(Extruder::current->enablePin > -1)
HAL::digitalWrite(Extruder::current->enablePin,!Extruder::current->enableOn);
#if FEATURE_DITTO_PRINTING
if(Extruder::dittoMode)
{
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if(extruder[1].enablePin > -1) {
HAL::digitalWrite(extruder[1].enablePin,!extruder[1].enableOn);
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#if defined(EXT1_MIRROR_STEPPER) && EXT1_MIRROR_STEPPER && NUM_EXTRUDER > 1
WRITE(EXT1_ENABLE2_PIN, !EXT1_ENABLE_ON);
#endif
}
#if NUM_EXTRUDER > 2
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if(Extruder::dittoMode > 1 && extruder[2].enablePin > -1) {
HAL::digitalWrite(extruder[2].enablePin,!extruder[2].enableOn);
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#if defined(EXT2_MIRROR_STEPPER) && EXT2_MIRROR_STEPPER && NUM_EXTRUDER > 2
WRITE(EXT2_ENABLE2_PIN, !EXT2_ENABLE_ON);
#endif
}
#endif
#if NUM_EXTRUDER > 3
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if(Extruder::dittoMode > 2 && extruder[3].enablePin > -1) {
HAL::digitalWrite(extruder[3].enablePin,!extruder[3].enableOn);
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#if defined(EXT3_MIRROR_STEPPER) && EXT3_MIRROR_STEPPER && NUM_EXTRUDER > 3
WRITE(EXT3_ENABLE2_PIN, !EXT3_ENABLE_ON);
#endif
}
#endif
}
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#endif
#endif
#endif // MIXING_EXTRUDER
}
void Extruder::disableAllExtruderMotors()
{
for(fast8_t i = 0; i < NUM_EXTRUDER; i++)
{
if(extruder[i].enablePin > -1)
HAL::digitalWrite(extruder[i].enablePin, !extruder[i].enableOn);
}
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#if defined(EXT0_MIRROR_STEPPER) && EXT0_MIRROR_STEPPER && NUM_EXTRUDER > 0
WRITE(EXT0_ENABLE2_PIN, !EXT0_ENABLE_ON);
#endif
#if defined(EXT1_MIRROR_STEPPER) && EXT1_MIRROR_STEPPER && NUM_EXTRUDER > 1
WRITE(EXT1_ENABLE2_PIN, !EXT1_ENABLE_ON);
#endif
#if defined(EXT2_MIRROR_STEPPER) && EXT2_MIRROR_STEPPER && NUM_EXTRUDER > 2
WRITE(EXT2_ENABLE2_PIN, !EXT2_ENABLE_ON);
#endif
#if defined(EXT3_MIRROR_STEPPER) && EXT3_MIRROR_STEPPER && NUM_EXTRUDER > 3
WRITE(EXT3_ENABLE2_PIN, !EXT3_ENABLE_ON);
#endif
#if defined(EXT4_MIRROR_STEPPER) && EXT4_MIRROR_STEPPER && NUM_EXTRUDER > 4
WRITE(EXT4_ENABLE2_PIN, !EXT4_ENABLE_ON);
#endif
#if defined(EXT5_MIRROR_STEPPER) && EXT5_MIRROR_STEPPER && NUM_EXTRUDER > 5
WRITE(EXT5_ENABLE2_PIN, !EXT5_ENABLE_ON);
#endif
}
#define NUMTEMPS_1 28
// Epcos B57560G0107F000
const short temptable_1[NUMTEMPS_1][2] PROGMEM =
{
{0,4000},{92,2400},{105,2320},{121,2240},{140,2160},{162,2080},{189,2000},{222,1920},{261,1840},{308,1760},
{365,1680},{434,1600},{519,1520},{621,1440},{744,1360},{891,1280},{1067,1200},{1272,1120},
{1771,960},{2357,800},{2943,640},{3429,480},{3760,320},{3869,240},{3912,200},{3948,160},{4077,-160},{4094,-440}
};
#define NUMTEMPS_2 21
const short temptable_2[NUMTEMPS_2][2] PROGMEM =
{
{1*4, 848*8},{54*4, 275*8}, {107*4, 228*8}, {160*4, 202*8},{213*4, 185*8}, {266*4, 171*8}, {319*4, 160*8}, {372*4, 150*8},
{425*4, 141*8}, {478*4, 133*8},{531*4, 125*8},{584*4, 118*8},{637*4, 110*8},{690*4, 103*8},{743*4, 95*8},{796*4, 86*8},
{849*4, 77*8},{902*4, 65*8},{955*4, 49*8},{1008*4, 17*8},{1020*4, 0*8} //safety
};
#define NUMTEMPS_3 28
const short temptable_3[NUMTEMPS_3][2] PROGMEM =
{
{1*4,864*8},{21*4,300*8},{25*4,290*8},{29*4,280*8},{33*4,270*8},{39*4,260*8},{46*4,250*8},{54*4,240*8},{64*4,230*8},{75*4,220*8},
{90*4,210*8},{107*4,200*8},{128*4,190*8},{154*4,180*8},{184*4,170*8},{221*4,160*8},{265*4,150*8},{316*4,140*8},{375*4,130*8},
{441*4,120*8},{513*4,110*8},{588*4,100*8},{734*4,80*8},{856*4,60*8},{938*4,40*8},{986*4,20*8},{1008*4,0*8},{1018*4,-20*8}
};
#define NUMTEMPS_4 20
const short temptable_4[NUMTEMPS_4][2] PROGMEM =
{
{1*4, 430*8},{54*4, 137*8},{107*4, 107*8},{160*4, 91*8},{213*4, 80*8},{266*4, 71*8},{319*4, 64*8},{372*4, 57*8},{425*4, 51*8},
{478*4, 46*8},{531*4, 41*8},{584*4, 35*8},{637*4, 30*8},{690*4, 25*8},{743*4, 20*8},{796*4, 14*8},{849*4, 7*8},{902*4, 0*8},
{955*4, -11*8},{1008*4, -35*8}
};
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// ATC 104GT
#define NUMTEMPS_8 34
const short temptable_8[NUMTEMPS_8][2] PROGMEM =
{
{0,8000},{69,2400},{79,2320},{92,2240},{107,2160},{125,2080},{146,2000},{172,1920},{204,1840},{222,1760},{291,1680},{350,1600},
{422,1520},{511,1440},{621,1360},{755,1280},{918,1200},{1114,1120},{1344,1040},{1608,960},{1902,880},{2216,800},{2539,720},
{2851,640},{3137,560},{3385,480},{3588,400},{3746,320},{3863,240},{3945,160},{4002,80},{4038,0},{4061,-80},{4075,-160}
};
#define NUMTEMPS_9 67 // 100k Honeywell 135-104LAG-J01
const short temptable_9[NUMTEMPS_9][2] PROGMEM =
{
{1*4, 941*8},{19*4, 362*8},{37*4, 299*8}, //top rating 300C
{55*4, 266*8},{73*4, 245*8},{91*4, 229*8},{109*4, 216*8},{127*4, 206*8},{145*4, 197*8},{163*4, 190*8},{181*4, 183*8},{199*4, 177*8},
{217*4, 171*8},{235*4, 166*8},{253*4, 162*8},{271*4, 157*8},{289*4, 153*8},{307*4, 149*8},{325*4, 146*8},{343*4, 142*8},{361*4, 139*8},
{379*4, 135*8},{397*4, 132*8},{415*4, 129*8},{433*4, 126*8},{451*4, 123*8},{469*4, 121*8},{487*4, 118*8},{505*4, 115*8},{523*4, 112*8},
{541*4, 110*8},{559*4, 107*8},{577*4, 105*8},{595*4, 102*8},{613*4, 99*8},{631*4, 97*8},{649*4, 94*8},{667*4, 92*8},{685*4, 89*8},
{703*4, 86*8},{721*4, 84*8},{739*4, 81*8},{757*4, 78*8},{775*4, 75*8},{793*4, 72*8},{811*4, 69*8},{829*4, 66*8},{847*4, 62*8},
{865*4, 59*8},{883*4, 55*8},{901*4, 51*8},{919*4, 46*8},{937*4, 41*8},
{955*4, 35*8},{973*4, 27*8},{991*4, 17*8},{1009*4, 1*8},{1023*4, 0} //to allow internal 0 degrees C
};
#define NUMTEMPS_10 20 // 100k 0603 SMD Vishay NTCS0603E3104FXT (4.7k pullup)
const short temptable_10[NUMTEMPS_10][2] PROGMEM =
{
{1*4, 704*8},{54*4, 216*8},{107*4, 175*8},{160*4, 152*8},{213*4, 137*8},{266*4, 125*8},{319*4, 115*8},{372*4, 106*8},{425*4, 99*8},
{478*4, 91*8},{531*4, 85*8},{584*4, 78*8},{637*4, 71*8},{690*4, 65*8},{743*4, 58*8},{796*4, 50*8},{849*4, 42*8},{902*4, 31*8},
{955*4, 17*8},{1008*4, 0}
};
#define NUMTEMPS_11 31 // 100k GE Sensing AL03006-58.2K-97-G1 (4.7k pullup)
const short temptable_11[NUMTEMPS_11][2] PROGMEM =
{
{1*4, 936*8},{36*4, 300*8},{71*4, 246*8},{106*4, 218*8},{141*4, 199*8},{176*4, 185*8},{211*4, 173*8},{246*4, 163*8},{281*4, 155*8},
{316*4, 147*8},{351*4, 140*8},{386*4, 134*8},{421*4, 128*8},{456*4, 122*8},{491*4, 117*8},{526*4, 112*8},{561*4, 107*8},{596*4, 102*8},
{631*4, 97*8},{666*4, 92*8},{701*4, 87*8},{736*4, 81*8},{771*4, 76*8},{806*4, 70*8},{841*4, 63*8},{876*4, 56*8},{911*4, 48*8},
{946*4, 38*8},{981*4, 23*8},{1005*4, 5*8},{1016*4, 0}
};
#define NUMTEMPS_12 31 // 100k RS thermistor 198-961 (4.7k pullup)
const short temptable_12[NUMTEMPS_12][2] PROGMEM =
{
{1*4, 929*8},{36*4, 299*8},{71*4, 246*8},{106*4, 217*8},{141*4, 198*8},{176*4, 184*8},{211*4, 173*8},{246*4, 163*8},{281*4, 154*8},{316*4, 147*8},
{351*4, 140*8},{386*4, 134*8},{421*4, 128*8},{456*4, 122*8},{491*4, 117*8},{526*4, 112*8},{561*4, 107*8},{596*4, 102*8},{631*4, 97*8},{666*4, 91*8},
{701*4, 86*8},{736*4, 81*8},{771*4, 76*8},{806*4, 70*8},{841*4, 63*8},{876*4, 56*8},{911*4, 48*8},{946*4, 38*8},{981*4, 23*8},{1005*4, 5*8},{1016*4, 0*8}
};
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#if CPU_ARCH == ARCH_AVR
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#define NUMTEMPS_13 19
const short temptable_13[NUMTEMPS_13][2] PROGMEM =
{
{0,0},{908,8},{942,10*8},{982,20*8},{1015,8*30},{1048,8*40},{1080,8*50},{1113,8*60},{1146,8*70},{1178,8*80},{1211,8*90},{1276,8*110},{1318,8*120}
,{1670,8*230},{2455,8*500},{3445,8*900},{3666,8*1000},{3871,8*1100},{4095,8*2000}
};
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#else
#define NUMTEMPS_13 9
const short temptable_13[NUMTEMPS_13][2] PROGMEM =
{
{0,0},{1365,8},{1427,10*8},{1489,20*8},{2532,8*230},{2842,8*300},{3301,8*400},{3723,8*500},{4095,8*600}
};
#endif
#define NUMTEMPS_14 46
const short temptable_14[NUMTEMPS_14][2] PROGMEM = {
{1*4,8*938}, {31*4,8*314}, {41*4,8*290}, {51*4,8*272}, {61*4,8*258}, {71*4,8*247}, {81*4,8*237}, {91*4,8*229}, {101*4,8*221}, {111*4,8*215}, {121*4,8*209},
{131*4,8*204}, {141*4,8*199}, {151*4,8*195}, {161*4,8*190}, {171*4,8*187}, {181*4,8*183}, {191*4,8*179}, {201*4,8*176}, {221*4,8*170}, {241*4,8*165},
{261*4,8*160}, {281*4,8*155}, {301*4,8*150}, {331*4,8*144}, {361*4,8*139}, {391*4,8*133}, {421*4,8*128}, {451*4,8*123}, {491*4,8*117}, {531*4,8*111},
{571*4,8*105}, {611*4,8*100}, {681*4,8*90}, {711*4,8*85}, {811*4,8*69}, {831*4,8*65}, {881*4,8*55},
{901*4,8*51}, {941*4,8*39}, {971*4,8*28}, {981*4,8*23}, {991*4,8*17}, {1001*4,8*9}, {1021*4,8*-27},{1023*4,8*-200}
};
#if NUM_TEMPS_USERTHERMISTOR0 > 0
const short temptable_5[NUM_TEMPS_USERTHERMISTOR0][2] PROGMEM = USER_THERMISTORTABLE0 ;
#endif
#if NUM_TEMPS_USERTHERMISTOR1 > 0
const short temptable_6[NUM_TEMPS_USERTHERMISTOR1][2] PROGMEM = USER_THERMISTORTABLE1 ;
#endif
#if NUM_TEMPS_USERTHERMISTOR2 > 0
const short temptable_7[NUM_TEMPS_USERTHERMISTOR2][2] PROGMEM = USER_THERMISTORTABLE2 ;
#endif
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const short * const temptables[14] PROGMEM = {(short int *)&temptable_1[0][0],(short int *)&temptable_2[0][0],(short int *)&temptable_3[0][0],(short int *)&temptable_4[0][0]
#if NUM_TEMPS_USERTHERMISTOR0 > 0
,(short int *)&temptable_5[0][0]
#else
,0
#endif
#if NUM_TEMPS_USERTHERMISTOR1 > 0
,(short int *)&temptable_6[0][0]
#else
,0
#endif
#if NUM_TEMPS_USERTHERMISTOR2 > 0
,(short int *)&temptable_7[0][0]
#else
,0
#endif
,(short int *)&temptable_8[0][0]
,(short int *)&temptable_9[0][0]
,(short int *)&temptable_10[0][0]
,(short int *)&temptable_11[0][0]
,(short int *)&temptable_12[0][0]
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,(short int *)&temptable_13[0][0]
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,(short int *)&temptable_14[0][0]
};
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const uint8_t temptables_num[14] PROGMEM = {NUMTEMPS_1,NUMTEMPS_2,NUMTEMPS_3,NUMTEMPS_4,NUM_TEMPS_USERTHERMISTOR0,NUM_TEMPS_USERTHERMISTOR1,NUM_TEMPS_USERTHERMISTOR2,NUMTEMPS_8,
NUMTEMPS_9,NUMTEMPS_10,NUMTEMPS_11,NUMTEMPS_12,NUMTEMPS_13,NUMTEMPS_14
};
void TemperatureController::updateCurrentTemperature()
{
uint8_t type = sensorType;
// get raw temperature
switch(type)
{
case 0:
currentTemperature = 25;
break;
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#if ANALOG_INPUTS > 0
case 1:
case 2:
case 3:
case 4:
case 5:
case 6:
case 7:
case 8:
case 9:
case 10:
case 11:
case 12:
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case 14:
case 97:
case 98:
case 99:
currentTemperature = (1023 << (2 - ANALOG_REDUCE_BITS)) - (osAnalogInputValues[sensorPin] >> (ANALOG_REDUCE_BITS)); // Convert to 10 bit result
break;
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case 13: // PT100 E3D
case 50: // User defined PTC table
case 51:
case 52:
case 60: // HEATER_USES_AD8495 (Delivers 5mV/degC)
case 61: // HEATER_USES_AD8495 (Delivers 5mV/degC) 1.25v offset
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case 100: // AD595 / AD597
currentTemperature = (osAnalogInputValues[sensorPin] >> (ANALOG_REDUCE_BITS));
break;
#endif
#ifdef SUPPORT_MAX6675
case 101: // MAX6675
currentTemperature = read_max6675(sensorPin);
break;
#endif
#ifdef SUPPORT_MAX31855
case 102: // MAX31855
currentTemperature = read_max31855(sensorPin);
break;
#endif
default:
currentTemperature = 4095; // unknown method, return high value to switch heater off for safety
}
int currentTemperature = this->currentTemperature;
//OUT_P_I_LN("OC for raw ",raw_temp);
switch(type)
{
case 0:
currentTemperatureC = 25;
break;
case 1:
case 2:
case 3:
case 4:
case 5:
case 6:
case 7:
case 8:
case 9:
case 10:
case 11:
case 12:
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case 14:
{
type--;
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uint8_t num = pgm_read_byte(&temptables_num[type]) << 1;
uint8_t i = 2;
const int16_t *temptable = (const int16_t *)pgm_read_word(&temptables[type]); //pgm_read_word_near(&temptables[type]);
int16_t oldraw = pgm_read_word(&temptable[0]);
int16_t oldtemp = pgm_read_word(&temptable[1]);
int16_t newraw,newtemp = 0;
currentTemperature = (1023 << (2 - ANALOG_REDUCE_BITS)) - currentTemperature;
while(i < num)
{
newraw = pgm_read_word(&temptable[i++]);
newtemp = pgm_read_word(&temptable[i++]);
if (newraw > currentTemperature)
{
//OUT_P_I("RC O:",oldtemp);OUT_P_I_LN(" OR:",oldraw);
//OUT_P_I("RC N:",newtemp);OUT_P_I_LN(" NR:",newraw);
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currentTemperatureC = TEMP_INT_TO_FLOAT(oldtemp + (float)(currentTemperature-oldraw)*(float)(newtemp - oldtemp) / (newraw - oldraw));
return;
}
oldtemp = newtemp;
oldraw = newraw;
}
// Overflow: Set to last value in the table
currentTemperatureC = TEMP_INT_TO_FLOAT(newtemp);
}
break;
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case 13:
case 50: // User defined PTC thermistor
case 51:
case 52:
{
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if(type > 49)
type -= 46;
else
type--;
uint8_t num = pgm_read_byte(&temptables_num[type]) << 1;
uint8_t i = 2;
const int16_t *temptable = (const int16_t *)pgm_read_word(&temptables[type]); //pgm_read_word_near(&temptables[type]);
int16_t oldraw = pgm_read_word(&temptable[0]);
int16_t oldtemp = pgm_read_word(&temptable[1]);
int16_t newraw,newtemp = 0;
while(i < num)
{
newraw = pgm_read_word(&temptable[i++]);
newtemp = pgm_read_word(&temptable[i++]);
if (newraw > currentTemperature)
{
currentTemperatureC = TEMP_INT_TO_FLOAT(oldtemp + (float)(currentTemperature-oldraw)*(float)(newtemp-oldtemp)/(newraw-oldraw));
return;
}
oldtemp = newtemp;
oldraw = newraw;
}
// Overflow: Set to last value in the table
currentTemperatureC = TEMP_INT_TO_FLOAT(newtemp);
break;
}
case 60: // AD8495 (Delivers 5mV/degC vs the AD595's 10mV)
#if CPU_ARCH == ARCH_AVR
currentTemperatureC = ((float)currentTemperature * 1000.0f / (1024 << (2 - ANALOG_REDUCE_BITS)));
#else
currentTemperatureC = ((float)currentTemperature * 660.0f / (1024 << (2 - ANALOG_REDUCE_BITS)));
#endif
break;
case 61: // AD8495 1.25V Vref offset (like Adafruit 8495 breakout board)
#if CPU_ARCH == ARCH_AVR
currentTemperatureC = ((float)currentTemperature * 1000.0f / (1024 << (2 - ANALOG_REDUCE_BITS))) - 250.0f;
#else
currentTemperatureC = ((float)currentTemperature * 660.0f / (1024 << (2 - ANALOG_REDUCE_BITS))) - 250.0f;
#endif
break;
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case 62: // TMP36
#if CPU_ARCH == ARCH_AVR
currentTemperatureC = ((float)currentTemperature * 500.0f / (1024 << (2 - ANALOG_REDUCE_BITS))) - 50.0f;
#else
currentTemperatureC = ((float)currentTemperature * 330.0f / (1024 << (2 - ANALOG_REDUCE_BITS))) - 50.0f;
#endif
break;
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case 100: // AD595 / AD597 10mV/°C
//return (int)((long)raw_temp * 500/(1024<<(2-ANALOG_REDUCE_BITS)));
#if CPU_ARCH == ARCH_AVR
currentTemperatureC = ((float)currentTemperature * 500.0f / (1024 << (2 - ANALOG_REDUCE_BITS)));
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#else
#if FEATURE_CONTROLLER == CONTROLLER_LCD_MP_PHARAOH_DUE
currentTemperatureC = ((float)currentTemperature * 500.0f / (1024 << (2 - ANALOG_REDUCE_BITS)));
#else
currentTemperatureC = ((float)currentTemperature * 330.0f / (1024 << (2 - ANALOG_REDUCE_BITS)));
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#endif
#endif
break;
#ifdef SUPPORT_MAX6675
case 101: // MAX6675
currentTemperatureC = (float)currentTemperature / 4.0;
break;
#endif
#ifdef SUPPORT_MAX31855
case 102: // MAX31855
currentTemperatureC = (float)currentTemperature / 4.0;
break;
#endif
#if defined(USE_GENERIC_THERMISTORTABLE_1) || defined(USE_GENERIC_THERMISTORTABLE_2) || defined(USE_GENERIC_THERMISTORTABLE_3)
case 97:
case 98:
case 99:
{
uint8_t i=2;
const short *temptable;
#ifdef USE_GENERIC_THERMISTORTABLE_1
if(type == 97)
temptable = (const short *)temptable_generic1;
#endif
#ifdef USE_GENERIC_THERMISTORTABLE_2
if(type == 98)
temptable = (const short *)temptable_generic2;
#endif
#ifdef USE_GENERIC_THERMISTORTABLE_3
if(type == 99)
temptable = (const short *)temptable_generic3;
#endif
short oldraw = temptable[0];
short oldtemp = temptable[1];
short newraw,newtemp;
currentTemperature = (1023 << (2 - ANALOG_REDUCE_BITS)) - currentTemperature;
while(i<GENERIC_THERM_NUM_ENTRIES*2)
{
newraw = temptable[i++];
newtemp = temptable[i++];
if (newraw > currentTemperature)
{
//OUT_P_I("RC O:",oldtemp);OUT_P_I_LN(" OR:",oldraw);
//OUT_P_I("RC N:",newtemp);OUT_P_I_LN(" NR:",newraw);
currentTemperatureC = TEMP_INT_TO_FLOAT(oldtemp + (float)(currentTemperature-oldraw)*(float)(newtemp-oldtemp)/(newraw-oldraw));
return;
}
oldtemp = newtemp;
oldraw = newraw;
}
// Overflow: Set to last value in the table
currentTemperatureC = TEMP_INT_TO_FLOAT(newtemp);
break;
}
#endif
}
}
void TemperatureController::setTargetTemperature(float target)
{
targetTemperatureC = target;
stopDecouple();
}
uint8_t autotuneIndex = 255;
void Extruder::disableAllHeater()
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{
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#if NUM_TEMPERATURE_LOOPS > 0
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for(uint8_t i = 0; i <= HEATED_BED_INDEX; i++)
{
TemperatureController *c = tempController[i];
c->targetTemperatureC = 0;
pwm_pos[c->pwmIndex] = 0;
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}
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#endif
autotuneIndex = 255;
}
#if TEMP_PID
void TemperatureController::autotunePID(float temp,uint8_t controllerId,int maxCycles,bool storeValues)
{
float currentTemp;
int cycles = 0;
bool heating = true;
uint32_t temp_millis = HAL::timeInMilliseconds();
uint32_t t1 = temp_millis;
uint32_t t2 = temp_millis;
int32_t t_high = 0;
int32_t t_low;
int32_t bias = pidMax >> 1;
int32_t d = pidMax >> 1;
float Ku, Tu;
float Kp = 0, Ki = 0, Kd = 0;
float maxTemp = 20, minTemp = 20;
if(maxCycles < 5)
maxCycles = 5;
if(maxCycles > 20)
maxCycles = 20;
Com::printInfoFLN(Com::tPIDAutotuneStart);
Extruder::disableAllHeater(); // switch off all heaters.
autotuneIndex = controllerId;
pwm_pos[pwmIndex] = pidMax;
if(controllerId<NUM_EXTRUDER)
{
extruder[controllerId].coolerPWM = extruder[controllerId].coolerSpeed;
extruder[0].coolerPWM = extruder[0].coolerSpeed;
}
for(;;)
{
#if FEATURE_WATCHDOG
HAL::pingWatchdog();
#endif // FEATURE_WATCHDOG
updateCurrentTemperature();
currentTemp = currentTemperatureC;
unsigned long time = HAL::timeInMilliseconds();
maxTemp = RMath::max(maxTemp,currentTemp);
minTemp = RMath::min(minTemp,currentTemp);
if(heating == true && currentTemp > temp) // switch heating -> off
{
if(time - t2 > (controllerId < NUM_EXTRUDER ? 2500 : 1500))
{
heating=false;
pwm_pos[pwmIndex] = (bias - d);
t1 = time;
t_high = t1 - t2;
maxTemp=temp;
}
}
if(heating == false && currentTemp < temp)
{
if(time - t1 > (controllerId < NUM_EXTRUDER ? 5000 : 3000))
{
heating = true;
t2 = time;
t_low=t2 - t1; // half wave length
if(cycles > 0)
{
bias += (d*(t_high - t_low))/(t_low + t_high);
bias = constrain(bias, 20 ,pidMax - 20);
if(bias > pidMax/2) d = pidMax - 1 - bias;
else d = bias;
Com::printF(Com::tAPIDBias,bias);
Com::printF(Com::tAPIDD,d);
Com::printF(Com::tAPIDMin,minTemp);
Com::printFLN(Com::tAPIDMax,maxTemp);
if(cycles > 2)
{
// Parameter according Ziegler¡§CNichols method: http://en.wikipedia.org/wiki/Ziegler%E2%80%93Nichols_method
Ku = (4.0 * d) / (3.14159*(maxTemp-minTemp));
Tu = ((float)(t_low + t_high)/1000.0);
Com::printF(Com::tAPIDKu,Ku);
Com::printFLN(Com::tAPIDTu,Tu);
Kp = 0.6*Ku;
Ki = 2*Kp/Tu;
Kd = Kp*Tu*0.125;
Com::printFLN(Com::tAPIDClassic);
Com::printFLN(Com::tAPIDKp,Kp);
Com::printFLN(Com::tAPIDKi,Ki);
Com::printFLN(Com::tAPIDKd,Kd);
/*
Kp = 0.33*Ku;
Ki = Kp/Tu;
Kd = Kp*Tu/3;
OUT_P_LN(" Some overshoot");
OUT_P_F_LN(" Kp: ",Kp);
OUT_P_F_LN(" Ki: ",Ki);
OUT_P_F_LN(" Kd: ",Kd);
Kp = 0.2*Ku;
Ki = 2*Kp/Tu;
Kd = Kp*Tu/3;
OUT_P_LN(" No overshoot");
OUT_P_F_LN(" Kp: ",Kp);
OUT_P_F_LN(" Ki: ",Ki);
OUT_P_F_LN(" Kd: ",Kd);
*/
}
}
pwm_pos[pwmIndex] = (bias + d);
cycles++;
minTemp=temp;
}
}
if(currentTemp > (temp + 40))
{
Com::printErrorFLN(Com::tAPIDFailedHigh);
Extruder::disableAllHeater();
return;
}
if(time - temp_millis > 1000)
{
temp_millis = time;
Commands::printTemperatures();
}
if(((time - t1) + (time - t2)) > (10L*60L*1000L*2L)) // 20 Minutes
{
Com::printErrorFLN(Com::tAPIDFailedTimeout);
Extruder::disableAllHeater();
return;
}
if(cycles > maxCycles)
{
Com::printInfoFLN(Com::tAPIDFinished);
Extruder::disableAllHeater();
if(storeValues)
{
pidPGain = Kp;
pidIGain = Ki;
pidDGain = Kd;
heatManager = HTR_PID;
EEPROM::storeDataIntoEEPROM();
}
return;
}
UI_MEDIUM;
UI_SLOW(true);
}
}
#endif
/** \brief Writes monitored temperatures.
This function is called every 250ms to write the monitored temperature. If monitoring is
disabled, the function is not called.
*/
void writeMonitor()
{
Commands::printTemperatures(false);
}
bool reportTempsensorError()
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{
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#if NUM_TEMPERATURE_LOOPS > 0
if(!Printer::isAnyTempsensorDefect()) return false;
for(uint8_t i = 0; i < NUM_TEMPERATURE_LOOPS; i++)
{
if(i == NUM_EXTRUDER) Com::printF(Com::tHeatedBed);
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#if HAVE_HEATED_BED
else if(i == HEATED_BED_INDEX) Com::printF(Com::tExtruderSpace,i);
#endif
else Com::printF(PSTR("Other:"));
TemperatureController *act = tempController[i];
int temp = act->currentTemperatureC;
if(temp < MIN_DEFECT_TEMPERATURE || temp > MAX_DEFECT_TEMPERATURE)
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Com::printF(Com::tTempSensorDefect);
else
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Com::printF(Com::tTempSensorWorking);
if(act->flags & TEMPERATURE_CONTROLLER_FLAG_SENSDEFECT)
Com::printF(PSTR(" marked defect"));
if(act->flags & TEMPERATURE_CONTROLLER_FLAG_SENSDECOUPLED)
Com::printF(PSTR(" marked decoupled"));
Com::println();
}
Com::printErrorFLN(Com::tDryModeUntilRestart);
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return true;
#else
return false;
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#endif
}
#ifdef SUPPORT_MAX6675
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int16_t read_max6675(uint8_t ss_pin)
{
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static millis_t last_max6675_read = 0;
static int16_t max6675_temp = 0;
if (HAL::timeInMilliseconds() - last_max6675_read > 230)
{
HAL::spiInit(2);
HAL::digitalWrite(ss_pin, 0); // enable TT_MAX6675
HAL::delayMicroseconds(1); // ensure 100ns delay - a bit extra is fine
max6675_temp = HAL::spiReceive(0);
max6675_temp <<= 8;
max6675_temp |= HAL::spiReceive(0);
HAL::digitalWrite(ss_pin, 1); // disable TT_MAX6675
last_max6675_read = HAL::timeInMilliseconds();
}
return max6675_temp & 4 ? 2000 : max6675_temp >> 3; // thermocouple open?
}
#endif
#ifdef SUPPORT_MAX31855
int16_t read_max31855(uint8_t ss_pin)
{
uint32_t data = 0;
int16_t temperature;
HAL::spiInit(2);
HAL::digitalWrite(ss_pin, 0); // enable TT_MAX31855
HAL::delayMicroseconds(1); // ensure 100ns delay - a bit extra is fine
for (unsigned short byte = 0; byte < 4; byte++)
{
data <<= 8;
data |= HAL::spiReceive();
}
HAL::digitalWrite(ss_pin, 1); // disable TT_MAX31855
//Process temp
if (data & 0x00010000)
return 20000; //Some form of error.
else
{
data = data >> 18;
temperature = data & 0x00001FFF;
if (data & 0x00002000)
{
data = ~data;
temperature = -1 * ((data & 0x00001FFF) + 1);
}
}
return temperature;
}
#endif
#if FEATURE_RETRACTION
void Extruder::retractDistance(float dist)
{
float oldFeedrate = Printer::feedrate;
int32_t distance = static_cast<int32_t>(dist * stepsPerMM / Printer::extrusionFactor);
int32_t oldEPos = Printer::currentPositionSteps[E_AXIS];
float speed = distance > 0 ? EEPROM_FLOAT(RETRACTION_SPEED) : EEPROM_FLOAT(RETRACTION_UNDO_SPEED);
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#if MIXING_EXTRUDER
Printer::setAllEMotors(true);
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#endif
PrintLine::moveRelativeDistanceInSteps(0, 0, 0, -distance, RMath::max(speed, 1.f), false, false);
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#if MIXING_EXTRUDER
Printer::setAllEMotors(false);
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#endif
Printer::currentPositionSteps[E_AXIS] = oldEPos; // restore previous extruder position
Printer::feedrate = oldFeedrate;
}
void Extruder::retract(bool isRetract,bool isLong)
{
float oldFeedrate = Printer::feedrate;
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float distance = (isLong ? EEPROM_FLOAT( RETRACTION_LONG_LENGTH) : EEPROM_FLOAT(RETRACTION_LENGTH));
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float zLiftF = EEPROM_FLOAT(RETRACTION_Z_LIFT);
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int32_t zlift = static_cast<int32_t>(zLiftF * Printer::axisStepsPerMM[Z_AXIS]);
if(isRetract && !isRetracted())
{
retractDistance(distance);
setRetracted(true);
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if(zlift > 0) {
PrintLine::moveRelativeDistanceInStepsReal(0,0,zlift,0,Printer::maxFeedrate[Z_AXIS], false);
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Printer::coordinateOffset[Z_AXIS] -= zLiftF;
}
}
else if(!isRetract && isRetracted())
{
distance += (isLong ? EEPROM_FLOAT(RETRACTION_UNDO_EXTRA_LONG_LENGTH) : EEPROM_FLOAT(RETRACTION_UNDO_EXTRA_LENGTH) );
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if(zlift > 0) {
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PrintLine::moveRelativeDistanceInStepsReal(0,0,-zlift,0,Printer::maxFeedrate[Z_AXIS], false);
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Printer::coordinateOffset[Z_AXIS] += zLiftF;
}
retractDistance(-distance);
setRetracted(false);
}
Printer::feedrate = oldFeedrate;
}
#endif
Extruder *Extruder::current;
#if NUM_EXTRUDER>0
const char ext0_select_cmd[] PROGMEM = EXT0_SELECT_COMMANDS;
const char ext0_deselect_cmd[] PROGMEM = EXT0_DESELECT_COMMANDS;
#endif
#if NUM_EXTRUDER>1
const char ext1_select_cmd[] PROGMEM = EXT1_SELECT_COMMANDS;
const char ext1_deselect_cmd[] PROGMEM = EXT1_DESELECT_COMMANDS;
#endif
#if NUM_EXTRUDER>2
const char ext2_select_cmd[] PROGMEM = EXT2_SELECT_COMMANDS;
const char ext2_deselect_cmd[] PROGMEM = EXT2_DESELECT_COMMANDS;
#endif
#if NUM_EXTRUDER>3
const char ext3_select_cmd[] PROGMEM = EXT3_SELECT_COMMANDS;
const char ext3_deselect_cmd[] PROGMEM = EXT3_DESELECT_COMMANDS;
#endif
#if NUM_EXTRUDER>4
const char ext4_select_cmd[] PROGMEM = EXT4_SELECT_COMMANDS;
const char ext4_deselect_cmd[] PROGMEM = EXT4_DESELECT_COMMANDS;
#endif
#if NUM_EXTRUDER>5
const char ext5_select_cmd[] PROGMEM = EXT5_SELECT_COMMANDS;
const char ext5_deselect_cmd[] PROGMEM = EXT5_DESELECT_COMMANDS;
#endif
#if NUM_EXTRUDER == 0
Extruder extruder[1];
#else
Extruder extruder[NUM_EXTRUDER] =
{
#if NUM_EXTRUDER > 0
{
0,EXT0_X_OFFSET,EXT0_Y_OFFSET,EXT0_Z_OFFSET,EXT0_STEPS_PER_MM,EXT0_ENABLE_PIN,EXT0_ENABLE_ON,
EXT0_MAX_FEEDRATE,EXT0_MAX_ACCELERATION,EXT0_MAX_START_FEEDRATE,0,EXT0_WATCHPERIOD
,EXT0_WAIT_RETRACT_TEMP,EXT0_WAIT_RETRACT_UNITS
#if USE_ADVANCE
#if ENABLE_QUADRATIC_ADVANCE
,EXT0_ADVANCE_K
#endif
,EXT0_ADVANCE_L,EXT0_ADVANCE_BACKLASH_STEPS
#endif
#if MIXING_EXTRUDER > 0
,10,10,{10,10,10,10,10,10,10,10,10,10,10,10,10,10,10,10}
#endif
,{
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0,EXT0_TEMPSENSOR_TYPE,EXT0_SENSOR_INDEX,EXT0_HEAT_MANAGER,0,0,0,0
#if TEMP_PID
,0,EXT0_PID_INTEGRAL_DRIVE_MAX,EXT0_PID_INTEGRAL_DRIVE_MIN,EXT0_PID_PGAIN_OR_DEAD_TIME,EXT0_PID_I,EXT0_PID_D,EXT0_PID_MAX,0,0,0,{0,0,0,0}
#endif
,0,0,0,EXT0_DECOUPLE_TEST_PERIOD
}
,ext0_select_cmd,ext0_deselect_cmd,EXT0_EXTRUDER_COOLER_SPEED,0,0,0
#if EXTRUDER_JAM_CONTROL
,0,0,10,0,0
#endif
}
#endif
#if NUM_EXTRUDER > 1
,{
1,EXT1_X_OFFSET,EXT1_Y_OFFSET,EXT1_Z_OFFSET,EXT1_STEPS_PER_MM,EXT1_ENABLE_PIN,EXT1_ENABLE_ON,
EXT1_MAX_FEEDRATE,EXT1_MAX_ACCELERATION,EXT1_MAX_START_FEEDRATE,0,EXT1_WATCHPERIOD
,EXT1_WAIT_RETRACT_TEMP,EXT1_WAIT_RETRACT_UNITS
#if USE_ADVANCE
#if ENABLE_QUADRATIC_ADVANCE
,EXT1_ADVANCE_K
#endif
,EXT1_ADVANCE_L,EXT1_ADVANCE_BACKLASH_STEPS
#endif
#if MIXING_EXTRUDER > 0
,10,10,{10,10,10,10,10,10,10,10,10,10,10,10,10,10,10,10}
#endif
,{
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1,EXT1_TEMPSENSOR_TYPE,EXT1_SENSOR_INDEX,EXT1_HEAT_MANAGER,0,0,0,0
#if TEMP_PID
,0,EXT1_PID_INTEGRAL_DRIVE_MAX,EXT1_PID_INTEGRAL_DRIVE_MIN,EXT1_PID_PGAIN_OR_DEAD_TIME,EXT1_PID_I,EXT1_PID_D,EXT1_PID_MAX,0,0,0,{0,0,0,0}
#endif
,0,0,0,EXT1_DECOUPLE_TEST_PERIOD
}
,ext1_select_cmd,ext1_deselect_cmd,EXT1_EXTRUDER_COOLER_SPEED,0,0,0
#if EXTRUDER_JAM_CONTROL
,0,0,10,0,0
#endif
}
#endif
#if NUM_EXTRUDER > 2
,{
2,EXT2_X_OFFSET,EXT2_Y_OFFSET,EXT2_Z_OFFSET,EXT2_STEPS_PER_MM,EXT2_ENABLE_PIN,EXT2_ENABLE_ON,
EXT2_MAX_FEEDRATE,EXT2_MAX_ACCELERATION,EXT2_MAX_START_FEEDRATE,0,EXT2_WATCHPERIOD
,EXT2_WAIT_RETRACT_TEMP,EXT2_WAIT_RETRACT_UNITS
#if USE_ADVANCE
#if ENABLE_QUADRATIC_ADVANCE
,EXT2_ADVANCE_K
#endif
,EXT2_ADVANCE_L,EXT2_ADVANCE_BACKLASH_STEPS
#endif
#if MIXING_EXTRUDER > 0
,10,10,{10,10,10,10,10,10,10,10,10,10,10,10,10,10,10,10}
#endif
,{
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2,EXT2_TEMPSENSOR_TYPE,EXT2_SENSOR_INDEX,EXT2_HEAT_MANAGER,0,0,0,0
#if TEMP_PID
,0,EXT2_PID_INTEGRAL_DRIVE_MAX,EXT2_PID_INTEGRAL_DRIVE_MIN,EXT2_PID_PGAIN_OR_DEAD_TIME,EXT2_PID_I,EXT2_PID_D,EXT2_PID_MAX,0,0,0,{0,0,0,0}
#endif
,0,0,0,EXT2_DECOUPLE_TEST_PERIOD
}
,ext2_select_cmd,ext2_deselect_cmd,EXT2_EXTRUDER_COOLER_SPEED,0,0,0
#if EXTRUDER_JAM_CONTROL
,0,0,10,0,0
#endif
}
#endif
#if NUM_EXTRUDER > 3
,{
3,EXT3_X_OFFSET,EXT3_Y_OFFSET,EXT3_Z_OFFSET,EXT3_STEPS_PER_MM,EXT3_ENABLE_PIN,EXT3_ENABLE_ON,
EXT3_MAX_FEEDRATE,EXT3_MAX_ACCELERATION,EXT3_MAX_START_FEEDRATE,0,EXT3_WATCHPERIOD
,EXT3_WAIT_RETRACT_TEMP,EXT3_WAIT_RETRACT_UNITS
#if USE_ADVANCE
#if ENABLE_QUADRATIC_ADVANCE
,EXT3_ADVANCE_K
#endif
,EXT3_ADVANCE_L,EXT3_ADVANCE_BACKLASH_STEPS
#endif
#if MIXING_EXTRUDER > 0
,10,10,{10,10,10,10,10,10,10,10,10,10,10,10,10,10,10,10}
#endif
,{
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3,EXT3_TEMPSENSOR_TYPE,EXT3_SENSOR_INDEX,EXT3_HEAT_MANAGER,0,0,0,0
#if TEMP_PID
,0,EXT3_PID_INTEGRAL_DRIVE_MAX,EXT3_PID_INTEGRAL_DRIVE_MIN,EXT3_PID_PGAIN_OR_DEAD_TIME,EXT3_PID_I,EXT3_PID_D,EXT3_PID_MAX,0,0,0,{0,0,0,0}
#endif
,0,0,0,EXT3_DECOUPLE_TEST_PERIOD
}
,ext3_select_cmd,ext3_deselect_cmd,EXT3_EXTRUDER_COOLER_SPEED,0,0,0
#if EXTRUDER_JAM_CONTROL
,0,0,10,0,0
#endif
}
#endif
#if NUM_EXTRUDER > 4
,{
4,EXT4_X_OFFSET,EXT4_Y_OFFSET,EXT4_Z_OFFSET,EXT4_STEPS_PER_MM,EXT4_ENABLE_PIN,EXT4_ENABLE_ON,
EXT4_MAX_FEEDRATE,EXT4_MAX_ACCELERATION,EXT4_MAX_START_FEEDRATE,0,EXT4_WATCHPERIOD
,EXT4_WAIT_RETRACT_TEMP,EXT4_WAIT_RETRACT_UNITS
#if USE_ADVANCE
#if ENABLE_QUADRATIC_ADVANCE
,EXT4_ADVANCE_K
#endif
,EXT4_ADVANCE_L,EXT4_ADVANCE_BACKLASH_STEPS
#endif
#if MIXING_EXTRUDER > 0
,10,10,{10,10,10,10,10,10,10,10,10,10,10,10,10,10,10,10}
#endif
,{
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4,EXT4_TEMPSENSOR_TYPE,EXT4_SENSOR_INDEX,EXT4_HEAT_MANAGER,0,0,0,0
#if TEMP_PID
,0,EXT4_PID_INTEGRAL_DRIVE_MAX,EXT4_PID_INTEGRAL_DRIVE_MIN,EXT4_PID_PGAIN_OR_DEAD_TIME,EXT4_PID_I,EXT4_PID_D,EXT4_PID_MAX,0,0,0,{0,0,0,0}
#endif
,0,0,0,EXT4_DECOUPLE_TEST_PERIOD
}
,ext4_select_cmd,ext4_deselect_cmd,EXT4_EXTRUDER_COOLER_SPEED,0,0,0
#if EXTRUDER_JAM_CONTROL
,0,0,10,0,0
#endif
}
#endif
#if NUM_EXTRUDER > 5
,{
5,EXT5_X_OFFSET,EXT5_Y_OFFSET,EXT5_Z_OFFSET,EXT5_STEPS_PER_MM,EXT5_ENABLE_PIN,EXT5_ENABLE_ON,
EXT5_MAX_FEEDRATE,EXT5_MAX_ACCELERATION,EXT5_MAX_START_FEEDRATE,0,EXT5_WATCHPERIOD
,EXT5_WAIT_RETRACT_TEMP,EXT5_WAIT_RETRACT_UNITS
#if USE_ADVANCE
#if ENABLE_QUADRATIC_ADVANCE
,EXT5_ADVANCE_K
#endif
,EXT5_ADVANCE_L,EXT5_ADVANCE_BACKLASH_STEPS
#endif
#if MIXING_EXTRUDER > 0
,10,10,{10,10,10,10,10,10,10,10,10,10,10,10,10,10,10,10}
#endif
,{
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5,EXT5_TEMPSENSOR_TYPE,EXT5_SENSOR_INDEX,EXT5_HEAT_MANAGER,0,0,0,0
#if TEMP_PID
,0,EXT5_PID_INTEGRAL_DRIVE_MAX,EXT5_PID_INTEGRAL_DRIVE_MIN,EXT5_PID_PGAIN_OR_DEAD_TIME,EXT5_PID_I,EXT5_PID_D,EXT5_PID_MAX,0,0,0,{0,0,0,0}
#endif
,0,0,0,EXT5_DECOUPLE_TEST_PERIOD
}
,ext5_select_cmd,ext5_deselect_cmd,EXT5_EXTRUDER_COOLER_SPEED,0,0,0
#if EXTRUDER_JAM_CONTROL
,0,0,10,0,0
#endif
}
#endif
};
#endif // NUM_EXTRUDER
#if HAVE_HEATED_BED
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TemperatureController heatedBedController = {PWM_HEATED_BED,HEATED_BED_SENSOR_TYPE,BED_SENSOR_INDEX,HEATED_BED_HEAT_MANAGER,0,0,0,0
#if TEMP_PID
,0,HEATED_BED_PID_INTEGRAL_DRIVE_MAX,HEATED_BED_PID_INTEGRAL_DRIVE_MIN,HEATED_BED_PID_PGAIN_OR_DEAD_TIME,HEATED_BED_PID_IGAIN,HEATED_BED_PID_DGAIN,HEATED_BED_PID_MAX,0,0,0,{0,0,0,0}
#endif
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,0,0,0,HEATED_BED_DECOUPLE_TEST_PERIOD};
#endif
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#if FAN_THERMO_PIN > -1
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TemperatureController thermoController = {PWM_FAN_THERMO,FAN_THERMO_THERMISTOR_TYPE,THERMO_ANALOG_INDEX,0,0,0,0,0
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#if TEMP_PID
,0,255,0,10,1,1,255,0,0,0,{0,0,0,0}
#endif
,0,0,0,0};
#endif
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#if NUM_TEMPERATURE_LOOPS > 0
TemperatureController *tempController[NUM_TEMPERATURE_LOOPS] =
{
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#if NUM_EXTRUDER > 0
&extruder[0].tempControl
#endif
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#if NUM_EXTRUDER > 1
,&extruder[1].tempControl
#endif
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#if NUM_EXTRUDER > 2
,&extruder[2].tempControl
#endif
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#if NUM_EXTRUDER > 3
,&extruder[3].tempControl
#endif
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#if NUM_EXTRUDER > 4
,&extruder[4].tempControl
#endif
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#if NUM_EXTRUDER > 5
,&extruder[5].tempControl
#endif
#if HAVE_HEATED_BED
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#if NUM_EXTRUDER == 0
&heatedBedController
#else
,&heatedBedController
#endif
#endif
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#if FAN_THERMO_PIN > -1
#if NUM_EXTRUDER == 0 && !HAVE_HEATED_BED
&thermoController
#else
,&thermoController
#endif
#endif // FAN_THERMO_PIN
};
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#endif