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Initialize.ino
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Initialize.ino
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// -----------------------------------------------------------------------------------
// Functions for initializing pins, variables, and timers on startup
void initPre() {
// disable the main axes stepper drivers
if (Axis1_EN != OFF) { pinMode(Axis1_EN,OUTPUT); digitalWrite(Axis1_EN,AXIS1_DRIVER_DISABLE); }
if (Axis2_EN != OFF && Axis2_EN != SHARED) { pinMode(Axis2_EN,OUTPUT); digitalWrite(Axis2_EN,AXIS2_DRIVER_DISABLE); }
// disable DS3234 CS pin
#if TIME_LOCATION_SOURCE == DS3234
pinMode(DS3234_CS_PIN,OUTPUT); digitalWrite(DS3234_CS_PIN,HIGH);
#endif
// disable weather CS pin
#if WEATHER == BMP280_SPI || WEATHER == BME280_SPI
pinMode(BME280_CS_PIN,OUTPUT); digitalWrite(BME280_CS_PIN,HIGH);
#endif
// disable all stepper driver CS pins at startup
#if AXIS1_DRIVER_MODEL == TMC_SPI
pinMode(Axis1_M2,OUTPUT); digitalWrite(Axis1_M2,HIGH);
#endif
#if AXIS2_DRIVER_MODEL == TMC_SPI
pinMode(Axis2_M2,OUTPUT); digitalWrite(Axis2_M2,HIGH);
#endif
#if AXIS3_DRIVER_MODEL == TMC_SPI
pinMode(Axis3_M2,OUTPUT); digitalWrite(Axis3_M2,HIGH);
#endif
#if AXIS4_DRIVER_MODEL == TMC_SPI
pinMode(Axis4_M2,OUTPUT); digitalWrite(Axis4_M2,HIGH);
#endif
#if AXIS5_DRIVER_MODEL == TMC_SPI
pinMode(Axis5_M2,OUTPUT); digitalWrite(Axis5_M2,HIGH);
#endif
}
void initPins() {
// Allow a given pin to supply power to devices
#ifdef GeneralPurposePowerPin1
pinMode(GeneralPurposePowerPin1,OUTPUT);
digitalWrite(GeneralPurposePowerPin1,HIGH);
#endif
#ifdef GeneralPurposePowerPin2
pinMode(GeneralPurposePowerPin2,OUTPUT);
digitalWrite(GeneralPurposePowerPin2,HIGH);
#endif
// Pull the Axis1/2 RST Pin HIGH on the MaxESP2
#if PINMAP == MaxESP2
pinMode(Axis1_M3,INPUT_PULLUP);
#endif
// light status LED (provides GND)
#if LED_STATUS == ON
pinMode(LEDnegPin,OUTPUT); digitalWrite(LEDnegPin,LOW);
#ifdef LEDposPin
pinMode(LEDposPin,OUTPUT); digitalWrite(LEDposPin,HIGH); // sometimes +5v is provided on a pin
#endif
ledOn=true;
#endif
// light status LED (provides pwm'd GND for polar reticule)
#if LED_STATUS >= 0
pinMode(LEDnegPin,OUTPUT); digitalWrite(LEDnegPin,LOW);
#ifdef LEDposPin
pinMode(LEDposPin,OUTPUT); digitalWrite(LEDposPin,HIGH); // sometimes +5v is provided on a pin
#endif
analogWrite(LEDnegPin,LED_STATUS);
ledOn=true;
#endif
// light reticule LED
#if LED_RETICLE >= 0
pinMode(ReticlePin,OUTPUT); analogWrite(ReticlePin,reticuleBrightness);
#endif
// light second status LED
#if LED_STATUS2 == ON
// provides just GND
pinMode(LEDneg2Pin,OUTPUT); digitalWrite(LEDneg2Pin,HIGH);
led2On=false;
#elif LED_STATUS2 >= 0
// provides pwm'd GND for polar reticule
pinMode(LEDneg2Pin,OUTPUT); digitalWrite(LEDneg2Pin,LOW);
analogWrite(LEDneg2Pin,LED_STATUS2);
#endif
// ready the sound/buzzer pin
#if BUZZER == ON || BUZZER >= 0
pinMode(TonePin,OUTPUT);
digitalWrite(TonePin,LOW);
#endif
// Home position sensing
#if HOME_SENSE == ON
pinMode(Axis1_HOME,INPUT);
pinMode(Axis2_HOME,INPUT);
#elif HOME_SENSE == ON_PULLUP
pinMode(Axis1_HOME,INPUT_PULLUP);
pinMode(Axis2_HOME,INPUT_PULLUP);
#elif HOME_SENSE == ON_PULLDOWN
pinMode(Axis1_HOME,INPUT_PULLDOWN);
pinMode(Axis2_HOME,INPUT_PULLDOWN);
#endif
// limit switch sense
#if LIMIT_SENSE == ON
pinMode(LimitPin,INPUT);
#elif LIMIT_SENSE == ON_PULLUP
pinMode(LimitPin,INPUT_PULLUP);
#elif LIMIT_SENSE == ON_PULLDOWN
pinMode(LimitPin,INPUT_PULLDOWN);
#endif
// PEC index sense
#if PEC_SENSE == ON
pinMode(PecPin,INPUT);
#elif PEC_SENSE == ON_PULLUP
pinMode(PecPin,INPUT_PULLUP);
#elif PEC_SENSE == ON_PULLDOWN
pinMode(PecPin,INPUT_PULLDOWN);
#endif
// Pulse per second
#if PPS_SENSE == ON
pinMode(PpsPin,INPUT);
attachInterrupt(digitalPinToInterrupt(PpsPin),clockSync,RISING);
#elif PPS_SENSE == ON_BOTH
pinMode(PpsPin,INPUT);
attachInterrupt(digitalPinToInterrupt(PpsPin),clockSync,CHANGE);
#elif PPS_SENSE == ON_PULLUP
pinMode(PpsPin,INPUT_PULLUP);
attachInterrupt(digitalPinToInterrupt(PpsPin),clockSync,RISING);
#elif PPS_SENSE == ON_PULLDOWN
pinMode(PpsPin,INPUT_PULLDOWN);
attachInterrupt(digitalPinToInterrupt(PpsPin),clockSync,RISING);
#endif
// Stepper driver control
pinMode(Axis1_STEP,OUTPUT);
pinMode(Axis1_DIR,OUTPUT);
pinMode(Axis2_STEP,OUTPUT);
pinMode(Axis2_DIR,OUTPUT);
#ifdef POWER_SUPPLY_PINS_ON
// provide 5V (or 3.3V) power to stepper drivers if requested (classic Pin-map)
pinMode(Axis15vPin,OUTPUT);
digitalWrite(Axis15vPin,HIGH);
pinMode(Axis25vPin,OUTPUT);
digitalWrite(Axis25vPin,HIGH);
#endif
#ifdef Axis2GndPin
// provide Gnd on next to the Dec stepper pins if requested (classic Pin-map)
pinMode(Axis2GndPin,OUTPUT);
digitalWrite(Axis2GndPin,LOW);
#endif
// inputs for stepper drivers fault signal
#if AXIS1_DRIVER_STATUS == LOW
pinMode(Axis1_FAULT,INPUT_PULLUP);
#elif AXIS1_DRIVER_STATUS == HIGH
#ifdef INPUT_PULLDOWN
pinMode(Axis1_FAULT,INPUT_PULLDOWN);
#else
pinMode(Axis1_FAULT,INPUT);
#endif
#endif
#if AXIS2_DRIVER_STATUS == LOW
pinMode(Axis2_FAULT,INPUT_PULLUP);
#elif AXIS1_DRIVER_STATUS == HIGH
#ifdef INPUT_PULLDOWN
pinMode(Axis2_FAULT,INPUT_PULLDOWN);
#else
pinMode(Axis2_FAULT,INPUT);
#endif
#endif
}
void initWriteNvValues() {
// EEPROM automatic initialization
if (NV_FACTORY_RESET == ON) nv.writeLong(EE_autoInitKey,0);
if (nv.readLong(EE_autoInitKey) != NV_INIT_KEY) {
// wipe the whole nv memory
VF("MSG: Wipe NV "); V(E2END+1); VLF(" Bytes (please wait)");
for (int i=0; i<E2END; i++) nv.write(i,0);
VLF("MSG: Init NV to defaults");
// default stepper driver setup is from Config.h
nv.write(EE_settingsRuntime,0);
// init the site information, lat/long/tz/name
nv.write(EE_currentSite,0);
latitude=0; longitude=0;
for (int l=0; l < 4; l++) {
nv.writeFloat(EE_sites+(l)*25+0,latitude);
nv.writeFloat(EE_sites+(l)*25+4,longitude);
nv.write(EE_sites+(l)*25+8,128);
nv.write(EE_sites+(l)*25+9,0);
}
// init the date and time January 1, 2013. 0 hours LMT
JD=CompilerDateToJulian();
LMT=0.0;
nv.writeFloat(EE_JD,JD);
nv.writeFloat(EE_LMT,LMT);
// init the degrees past meridian east/west
nv.write(EE_dpmE,round(AXIS1_LIMIT_MERIDIAN_E+128));
nv.write(EE_dpmW,round(AXIS1_LIMIT_MERIDIAN_W+128));
// init the min and max altitude
minAlt=-10;
maxAlt=80;
nv.write(EE_minAlt,minAlt+128);
nv.write(EE_maxAlt,maxAlt);
// init (clear) the backlash amounts
nv.writeInt(EE_backlashAxis2,0);
nv.writeInt(EE_backlashAxis1,0);
// init the PEC status, clear the index and buffer
nv.write(EE_pecStatus,IgnorePEC);
nv.write(EE_pecRecorded,false);
wormSensePos=0;
nv.writeLong(EE_wormSensePos,wormSensePos);
// init the Park status
nv.write(EE_parkSaved,false);
nv.write(EE_parkStatus,NotParked);
// init the pulse-guide rate
nv.write(EE_pulseGuideRate,GuideRate1x);
// init the default maxRate
maxRate=((1000000.0/(SLEW_RATE_BASE_DESIRED))/AXIS1_STEPS_PER_DEGREE)*16L;
if (maxRate < 2L*16L) maxRate=2L*16L;
if (maxRate > 10000L*16L) maxRate=10000L*16L;
if (maxRate < maxRateLowerLimit()) maxRate=maxRateLowerLimit();
nv.writeInt(EE_maxRate,-1); nv.writeLong(EE_maxRateL,maxRate);
// init autoMeridianFlip
nv.write(EE_autoMeridianFlip,autoMeridianFlip);
// init the sidereal tracking rate
// 1/16uS resolution timer, ticks per sidereal second
nv.writeLong(EE_siderealInterval,masterSiderealInterval);
// set default focuser positions at zero
// for DC focusers set the % power
// clear focuser TCF values
long base=EE_focBaseAxis4;
nv.writeLong(base+EE_focSpos,0L);
nv.writeLong(base+EE_focTarget,0L);
nv.writeInt(base+EE_focBacklashPos,0);
nv.writeInt(base+EE_focBacklash,0);
nv.write(base+EE_focDcPwr,50);
nv.writeFloat(base+EE_tcfCoef,0.0);
nv.write(base+EE_tcfEn,0);
nv.writeInt(base+EE_tcfDeadband,1);
nv.writeFloat(base+EE_tcfT0,10.0);
base=EE_focBaseAxis5;
nv.writeLong(base+EE_focSpos,0L);
nv.writeLong(base+EE_focTarget,0L);
nv.writeInt(base+EE_focBacklashPos,0);
nv.writeInt(base+EE_focBacklash,0);
nv.write(base+EE_focDcPwr,50);
nv.writeFloat(base+EE_tcfCoef,0.0);
nv.write(base+EE_tcfEn,0);
nv.writeInt(base+EE_tcfDeadband,1);
nv.writeFloat(base+EE_tcfT0,10.0);
// clear the library/catalogs
Lib.clearAll();
// clear the pointing model
saveAlignModel();
// sit here and wait until the entire nv contents are written before writing the key
VLF("MSG: Init NV waiting for cache");
#ifndef ESP32
while (!nv.committed()) nv.poll();
#endif
// finally, stop the init from happening again
nv.writeLong(EE_autoInitKey,NV_INIT_KEY);
VLF("MSG: Init NV key written");
}
// bit 0 = settings at compile (0) or run time (1), bits 1 to 5 = (1) to reset axis n on next boot
int axisReset=nv.read(EE_settingsRuntime);
if (!(axisReset&0b0000001)) axisReset|=0b0111110; // force reset of all axis settings
if (axisReset&0b0000010) { nv.writeBytes(EE_settingsAxis1,(byte*)&axis1Settings,sizeof(axis1Settings)); nv.writeLong(EE_stepsPerWormRotAxis1,AXIS1_STEPS_PER_WORMROT); VLF("MSG: Init NV Axis1 defaults"); }
if (axisReset&0b0000100) { nv.writeBytes(EE_settingsAxis2,(byte*)&axis2Settings,sizeof(axis2Settings)); VLF("MSG: Init NV Axis2 defaults"); }
if (axisReset&0b0001000) { nv.writeBytes(EE_settingsAxis3,(byte*)&axis3Settings,sizeof(axis3Settings)); VLF("MSG: Init NV Axis3 defaults"); }
if (axisReset&0b0010000) { nv.writeBytes(EE_settingsAxis4,(byte*)&axis4Settings,sizeof(axis4Settings)); VLF("MSG: Init NV Axis4 defaults"); }
if (axisReset&0b0100000) { nv.writeBytes(EE_settingsAxis5,(byte*)&axis5Settings,sizeof(axis5Settings)); VLF("MSG: Init NV Axis5 defaults"); }
axisReset&=0b0000001; // clear reset bits of all individual axis settings
nv.write(EE_settingsRuntime,axisReset);
}
void initReadNvValues() {
if (E2END < 1023) { generalError=ERR_NV_INIT; DLF("ERR, initReadNvValues(): bad NV size < 1024 bytes"); }
// get axis settings
nv.readBytes(EE_settingsAxis1,(byte*)&axis1Settings,sizeof(axis1Settings));
nv.readBytes(EE_settingsAxis2,(byte*)&axis2Settings,sizeof(axis2Settings));
nv.readBytes(EE_settingsAxis3,(byte*)&axis3Settings,sizeof(axis3Settings));
nv.readBytes(EE_settingsAxis4,(byte*)&axis4Settings,sizeof(axis4Settings));
nv.readBytes(EE_settingsAxis5,(byte*)&axis5Settings,sizeof(axis5Settings));
if (axis1Settings.IRUN != AXIS1_DRIVER_IRUN) { axis1SettingsEx.IGOTO=axis1Settings.IRUN; axis1SettingsEx.IHOLD=axis1Settings.IRUN/2; }
if (!validateAxisSettings(1,MOUNT_TYPE==ALTAZM,axis1Settings)) generalError=ERR_NV_INIT;
if (axis2Settings.IRUN != AXIS2_DRIVER_IRUN) { axis2SettingsEx.IGOTO=axis2Settings.IRUN; axis2SettingsEx.IHOLD=axis2Settings.IRUN/2; }
if (!validateAxisSettings(2,MOUNT_TYPE==ALTAZM,axis2Settings)) generalError=ERR_NV_INIT;
if (axis3Settings.IRUN != AXIS3_DRIVER_IRUN) axis3SettingsEx.IHOLD=axis3Settings.IRUN/2;
if (!validateAxisSettings(3,MOUNT_TYPE==ALTAZM,axis3Settings)) generalError=ERR_NV_INIT;
if (axis4Settings.IRUN != AXIS4_DRIVER_IRUN) axis4SettingsEx.IHOLD=axis4Settings.IRUN/2;
if (!validateAxisSettings(4,MOUNT_TYPE==ALTAZM,axis4Settings)) generalError=ERR_NV_INIT;
if (axis5Settings.IRUN != AXIS5_DRIVER_IRUN) axis5SettingsEx.IHOLD=axis5Settings.IRUN/2;
if (!validateAxisSettings(5,MOUNT_TYPE==ALTAZM,axis5Settings)) generalError=ERR_NV_INIT;
timerRateRatio = axis1Settings.stepsPerMeasure/axis2Settings.stepsPerMeasure;
useTimerRateRatio = axis1Settings.stepsPerMeasure != axis2Settings.stepsPerMeasure;
#if AXIS1_DRIVER_MODEL != SERVO && AXIS1_DRIVER_MODEL != SERVO1 && AXIS1_DRIVER_MODEL != SERVO2
if (AXIS1_DRIVER_MICROSTEPS_GOTO != OFF) axis1StepsGoto = axis1Settings.microsteps/AXIS1_DRIVER_MICROSTEPS_GOTO;
#else
if (AXIS1_DRIVER_MICROSTEPS_GOTO != OFF) axis1StepsGoto = AXIS1_DRIVER_MICROSTEPS_GOTO/axis1Settings.microsteps;
#endif
#if AXIS2_DRIVER_MODEL != SERVO && AXIS2_DRIVER_MODEL != SERVO1 && AXIS2_DRIVER_MODEL != SERVO2
if (AXIS2_DRIVER_MICROSTEPS_GOTO != OFF) axis2StepsGoto = axis2Settings.microsteps/AXIS2_DRIVER_MICROSTEPS_GOTO;
#else
if (AXIS2_DRIVER_MICROSTEPS_GOTO != OFF) axis2StepsGoto = AXIS2_DRIVER_MICROSTEPS_GOTO/axis2Settings.microsteps;
#endif
// Basic stepper driver mode setup
// if we made through validation and AXIS1_DRIVER_MODEL exists; AXIS2_DRIVER_MODEL, axis1Settings.microsteps,
// and axis2Settings.microsteps also exist and passed validation in the pre-processor
#if AXIS1_DRIVER_MODEL != OFF
// translate microsteps to microstep bit code
AXIS1_DRIVER_CODE = translateMicrosteps(AXIS1_DRIVER_MODEL, axis1Settings.microsteps);
AXIS2_DRIVER_CODE = translateMicrosteps(AXIS2_DRIVER_MODEL, axis2Settings.microsteps);
#if AXIS1_DRIVER_MICROSTEPS_GOTO != OFF
AXIS1_DRIVER_CODE_GOTO = translateMicrosteps(AXIS1_DRIVER_MODEL, AXIS1_DRIVER_MICROSTEPS_GOTO);
#endif
#if AXIS2_DRIVER_MICROSTEPS_GOTO != OFF
AXIS2_DRIVER_CODE_GOTO = translateMicrosteps(AXIS2_DRIVER_MODEL, AXIS2_DRIVER_MICROSTEPS_GOTO);
#endif
#endif
#if AXIS3_DRIVER_MODEL != OFF
AXIS3_DRIVER_CODE = translateMicrosteps(AXIS3_DRIVER_MODEL, axis3Settings.microsteps);
#endif
#if AXIS4_DRIVER_MODEL != OFF
AXIS4_DRIVER_CODE = translateMicrosteps(AXIS4_DRIVER_MODEL, axis4Settings.microsteps);
#endif
#if AXIS5_DRIVER_MODEL != OFF
AXIS5_DRIVER_CODE = translateMicrosteps(AXIS5_DRIVER_MODEL, axis5Settings.microsteps);
#endif
// get the site information, if a GPS were attached we would use that here instead
currentSite=nv.read(EE_currentSite);
if (currentSite > 3) { currentSite=0; generalError=ERR_NV_INIT; DLF("ERR, initReadNvValues(): bad NV currentSite"); }
double f=nv.readFloat(EE_sites+currentSite*25+0);
if (f < -90 || f > 90) { f=0.0; generalError=ERR_NV_INIT; DLF("ERR, initReadNvValues(): bad NV latitude"); }
setLatitude(f);
longitude=nv.readFloat(EE_sites+currentSite*25+4);
if (longitude < -360 || longitude > 360) { longitude=0.0; generalError=ERR_NV_INIT; DLF("ERR, initReadNvValues(): bad NV longitude"); }
// get date and time from EEPROM, start keeping time
timeZone=nv.read(EE_sites+currentSite*25+8)-128;
timeZone=decodeTimeZone(timeZone);
if (timeZone < -14 || timeZone > 12) { timeZone=0.0; generalError=ERR_NV_INIT; DLF("ERR, initReadNvValues(): bad NV timeZone"); }
nv.readString(EE_sites+currentSite*25+9,siteName);
JD=nv.readFloat(EE_JD);
LMT=nv.readFloat(EE_LMT);
if (tls.active) {
tls.get(JD,LMT); // read the date/time from TLS (if present)
dateWasSet=true; timeWasSet=true;
}
if (JD < 2451544.5 || JD > 2816787.5) JD=2451544.5; // valid date?
if (LMT < 0 || LMT > 24) { LMT=0; generalError=ERR_NV_INIT; DLF("ERR, initReadNvValues(): bad NV LMT"); }
UT1=LMT+timeZone;
updateLST(jd2last(JD,UT1,false));
// get the degrees past meridian east/west
#if MOUNT_TYPE == GEM
int i=round(nv.read(EE_dpmE)-128);
if (i > 60) i=((i-60)*2)+60; else if (i < -60) i=((i+60)*2)-60;
degreesPastMeridianE=i;
if (degreesPastMeridianE < -180 || degreesPastMeridianE > 180) { degreesPastMeridianE=0.0; generalError=ERR_NV_INIT; DLF("ERR, initReadNvValues(): bad NV degreesPastMeridianE"); }
i=round(nv.read(EE_dpmW)-128);
if (i > 60) i=((i-60)*2)+60; else if (i < -60) i=((i+60)*2)-60;
degreesPastMeridianW=i;
if (degreesPastMeridianW < -180 || degreesPastMeridianW > 180) { degreesPastMeridianW=0.0; generalError=ERR_NV_INIT; DLF("ERR, initReadNvValues(): bad NV degreesPastMeridianW"); }
#endif
// get the min. and max altitude
minAlt=nv.read(EE_minAlt)-128;
if (minAlt < -30 || minAlt > 30) { minAlt=-10.0; generalError=ERR_NV_INIT; DLF("ERR, initReadNvValues(): bad NV minAlt"); }
maxAlt=nv.read(EE_maxAlt);
#if MOUNT_TYPE == ALTAZM
if (maxAlt > 87) maxAlt=87;
#endif
if (maxAlt < 60 || maxAlt > 90) { maxAlt=80.0; generalError=ERR_NV_INIT; DLF("ERR, initReadNvValues(): bad NV maxAlt"); }
// get the backlash amounts
backlashAxis1=nv.readInt(EE_backlashAxis1);
if (backlashAxis1 < 0 ) { backlashAxis1=0; generalError=ERR_NV_INIT; DLF("ERR, initReadNvValues(): bad NV backlashAxis1"); }
backlashAxis2=nv.readInt(EE_backlashAxis2);
if (backlashAxis2 < 0 ) { backlashAxis2=0; generalError=ERR_NV_INIT; DLF("ERR, initReadNvValues(): bad NV backlashAxis2"); }
// setup PEC and get data
if (AXIS1_PEC != ON) nv.writeLong(EE_stepsPerWormRotAxis1,0);
stepsPerWormRotationAxis1=nv.readLong(EE_stepsPerWormRotAxis1);
secondsPerWormRotationAxis1=stepsPerWormRotationAxis1/stepsPerSecondAxis1;
pecBufferSize=ceil(stepsPerWormRotationAxis1/(axis1Settings.stepsPerMeasure/240.0));
if (pecBufferSize != 0) {
if (pecBufferSize < 61) { pecBufferSize=0; generalError=ERR_NV_INIT; DLF("ERR, initReadNvValues(): invalid pecBufferSize, PEC disabled"); }
if (200+pecBufferSize >= E2END-200) { pecBufferSize=0; generalError=ERR_NV_INIT; DLF("ERR, initReadNvValues(): pecBufferSize exceeds available NV, PEC disabled"); }
}
if (secondsPerWormRotationAxis1 > pecBufferSize) secondsPerWormRotationAxis1=pecBufferSize;
#if AXIS1_PEC == ON
createPecBuffer();
bool pecBufferNeedsInit=true;
for (int i=0; i < pecBufferSize; i++) { pecBuffer[i]=nv.read(EE_pecTable+i); if (pecBuffer[i] != 0) pecBufferNeedsInit=false; }
if (pecBufferNeedsInit) for (int l=0; l < pecBufferSize; l++) nv.write(EE_pecTable+l,128);
wormSensePos=nv.readLong(EE_wormSensePos); // validation of this value is not useful
#if PEC_SENSE == OFF
wormSensePos=0;
pecStatus=IgnorePEC;
#endif
pecStatus=nv.read(EE_pecStatus);
if (pecStatus < PEC_STATUS_FIRST || pecStatus > PEC_STATUS_LAST) { pecStatus=IgnorePEC; generalError=ERR_NV_INIT; DLF("ERR, initReadNvValues(): bad NV pecStatus"); }
pecRecorded=nv.read(EE_pecRecorded);
if (pecRecorded != true && pecRecorded != false) { pecRecorded=false; generalError=ERR_NV_INIT; DLF("ERR, initReadNvValues(): bad NV pecRecorded"); }
if (!pecRecorded) pecStatus=IgnorePEC;
#endif
// get the Park status
parkSaved=nv.read(EE_parkSaved);
if (parkSaved != true && parkSaved != false) { parkSaved=false; generalError=ERR_NV_INIT; DLF("ERR, initReadNvValues(): bad NV parkSaved"); }
parkStatus=nv.read(EE_parkStatus);
if (parkStatus < PARK_STATUS_FIRST || parkStatus > PARK_STATUS_LAST) { parkStatus=NotParked; generalError=ERR_NV_INIT; DLF("ERR, initReadNvValues(): bad NV parkStatus"); }
// tried to park but crashed?
if (parkStatus == Parking) { parkStatus=ParkFailed; nv.write(EE_parkStatus,parkStatus); }
// get the pulse-guide rate
currentPulseGuideRate=nv.read(EE_pulseGuideRate);
if (currentPulseGuideRate < 0) { currentPulseGuideRate=0; generalError=ERR_NV_INIT; DLF("ERR, initReadNvValues(): bad NV currentPulseGuideRate"); }
if (currentPulseGuideRate > GuideRate1x) { currentPulseGuideRate=GuideRate1x; generalError=ERR_NV_INIT; DLF("ERR, initReadNvValues(): bad NV currentPulseGuideRate"); }
// set the default MaxRate based on the desired goto speed
maxRateBaseActual=maxRateBaseDesired;
if (maxRateBaseActual < maxRateLowerLimit()/8.0) maxRateBaseActual=maxRateLowerLimit()/8.0;
if (maxRateBaseActual > 1000000.0) maxRateBaseActual=1000000.0;
// get the max goto rate
maxRate=(int16_t)nv.readInt(EE_maxRate)*16; // maxRate is in 16MHz clocks but stored in micro-seconds
// check for flag that maxRate is stored in EE_maxRateL, if not move it there
if (maxRate == -16) maxRate=nv.readLong(EE_maxRateL); else { nv.writeInt(EE_maxRate,-1); nv.writeLong(EE_maxRateL,maxRate); }
// constrain values to the limits (1/2 to 2X the maxRateBaseActual) and platform limits
if (maxRate < (long)(maxRateBaseActual*8.0)) { maxRate=maxRateBaseActual*8.0; DLF("WRN, initReadNvValues(): NV maxRate (too low)"); }
if (maxRate > (long)(maxRateBaseActual*32.0)) { maxRate=maxRateBaseActual*32.0; DLF("WRN, initReadNvValues(): NV maxRate (too high)"); }
if (maxRate < maxRateLowerLimit()) maxRate=maxRateLowerLimit();
#if SLEW_RATE_MEMORY == OFF
if (maxRate != (long)(maxRateBaseActual*16.0)) { maxRate=maxRateBaseActual*16.0; nv.writeLong(EE_maxRateL,maxRate); }
#endif
// set the new acceleration rate
setAccelerationRates(maxRate);
// get autoMeridianFlip
#if MOUNT_TYPE == GEM && MFLIP_AUTOMATIC_MEMORY == ON
autoMeridianFlip=nv.read(EE_autoMeridianFlip);
if (autoMeridianFlip != 1 && autoMeridianFlip != 0) { autoMeridianFlip=0; generalError=ERR_NV_INIT; DLF("ERR, initReadNvValues(): bad NV autoMeridianFlip"); }
#endif
// get meridian flip pause at home
#if MOUNT_TYPE == GEM && MFLIP_PAUSE_HOME_MEMORY == ON
pauseHome=nv.read(EE_pauseHome);
if (pauseHome != 1 && pauseHome != 0) { pauseHome=0; generalError=ERR_NV_INIT; DLF("ERR, initReadNvValues(): bad NV pauseHome"); }
#endif
// set the default guide rate
setGuideRate(GuideRateDefault);
enableGuideRate(GuideRateDefault);
}
void initGeneralError() {
switch (generalError) {
case ERR_ALT_MIN:
case ERR_LIMIT_SENSE:
case ERR_DEC:
case ERR_AZM:
case ERR_UNDER_POLE:
case ERR_MERIDIAN:
case ERR_SYNC:
case ERR_ALT_MAX:
case ERR_PARK: generalError=ERR_NONE; break;
default: break;
}
}
void initStartupValues() {
// initialize some fixed-point values
amountGuideAxis1.fixed= 0;
amountGuideAxis2.fixed= 0;
guideAxis1.fixed = 0;
guideAxis2.fixed = 0;
accPecGuideHA.fixed = 0;
fstepAxis1.fixed = 0;
fstepAxis2.fixed = 0;
origTargetAxis1.fixed = 0;
// default values for state variables
pierSideControl = PierSideNone;
dirAxis1 = 1;
if (latitude >= 0) {
if (axis1Settings.reverse == ON) defaultDirAxis1 = DefaultDirAxis1SCPInit; else defaultDirAxis1 = DefaultDirAxis1NCPInit;
} else {
if (axis1Settings.reverse == ON) defaultDirAxis1 = DefaultDirAxis1NCPInit; else defaultDirAxis1 = DefaultDirAxis1SCPInit;
}
dirAxis2 = 1;
if (axis2Settings.reverse == ON) defaultDirAxis2 = DefaultDirAxis2WInit; else defaultDirAxis2 = DefaultDirAxis2EInit;
newTargetRA = 0;
newTargetDec = 0;
newTargetAlt = 0;
newTargetAzm = 0;
origTargetAxis1.fixed = 0;
origTargetAxis2.fixed = 0;
// initialize alignment
alignNumStars = 0;
alignThisStar = 0;
indexAxis1 = 0;
indexAxis1Steps = 0;
indexAxis2 = 0;
indexAxis2Steps = 0;
Align.init();
// reset meridian flip control
#if MOUNT_TYPE == GEM
meridianFlip = MeridianFlipAlways;
#endif
#if MOUNT_TYPE == FORK
meridianFlip = MeridianFlipNever;
#endif
#if MOUNT_TYPE == ALTAZM
meridianFlip = MeridianFlipNever;
#endif
// clear errors that are no-longer relevant after init
initGeneralError();
// where we are
homeMount = false;
atHome = true;
waitingHome = false;
waitingHomeContinue = false;
// reset tracking and rates
cli();
trackingState = TrackingNone;
lastTrackingState = TrackingNone;
timerRateAxis1 = siderealRate;
timerRateAxis2 = siderealRate;
sei();
}
// the start position
void initStartPosition() {
startAxis1 = 0;
startAxis2 = 0;
cli();
targetAxis1.part.m = 0; targetAxis1.part.f = 0;
posAxis1 = 0;
blAxis1 = 0;
targetAxis2.part.m = 0; targetAxis2.part.f = 0;
posAxis2 = 0;
blAxis2 = 0;
sei();
setIndexAxis1(homePositionAxis1,PierSideEast);
setIndexAxis2(homePositionAxis2,PierSideEast);
}
void initStartTimers() {
// Initialize the timers that handle the sidereal clock, RA, and Dec
HAL_Init_Timer_Sidereal();
// wait for the sidereal clock to tick
delay(15);
// Initialize Axis1 and Axis2 motor timers and set their priorities
HAL_Init_Timers_Motor();
}