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CommandStation-EX/TrackManager.cpp

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/*
* © 2022 Chris Harlow
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* © 2022 Harald Barth
* © 2023 Colin Murdoch
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* All rights reserved.
*
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* This file is part of DCC++EX
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*
* This 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.
*
* It 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 CommandStation. If not, see <https://www.gnu.org/licenses/>.
*/
#include "TrackManager.h"
#include "FSH.h"
#include "DCCWaveform.h"
#include "DCC.h"
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#include "MotorDriver.h"
#include "DCCTimer.h"
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#include "DIAG.h"
#include"CommandDistributor.h"
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// Virtualised Motor shield multi-track hardware Interface
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#define FOR_EACH_TRACK(t) for (byte t=0;t<=lastTrack;t++)
#define APPLY_BY_MODE(findmode,function) \
FOR_EACH_TRACK(t) \
if (track[t]->getMode()==findmode) \
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track[t]->function;
#ifndef DISABLE_PROG
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const int16_t HASH_KEYWORD_PROG = -29718;
#endif
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const int16_t HASH_KEYWORD_MAIN = 11339;
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const int16_t HASH_KEYWORD_OFF = 22479;
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const int16_t HASH_KEYWORD_NONE = -26550;
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const int16_t HASH_KEYWORD_DC = 2183;
const int16_t HASH_KEYWORD_DCX = 6463; // DC reversed polarity
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const int16_t HASH_KEYWORD_EXT = 8201; // External DCC signal
const int16_t HASH_KEYWORD_A = 65; // parser makes single chars the ascii.
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MotorDriver * TrackManager::track[MAX_TRACKS];
int16_t TrackManager::trackDCAddr[MAX_TRACKS];
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POWERMODE TrackManager::mainPowerGuess=POWERMODE::OFF;
byte TrackManager::lastTrack=0;
bool TrackManager::progTrackSyncMain=false;
bool TrackManager::progTrackBoosted=false;
int16_t TrackManager::joinRelay=UNUSED_PIN;
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#ifdef ARDUINO_ARCH_ESP32
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byte TrackManager::tempProgTrack=MAX_TRACKS+1; // MAX_TRACKS+1 is the unused flag
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#endif
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#ifdef ANALOG_READ_INTERRUPT
/*
* sampleCurrent() runs from Interrupt
*/
void TrackManager::sampleCurrent() {
static byte tr = 0;
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byte trAtStart = tr;
static bool waiting = false;
if (waiting) {
if (! track[tr]->sampleCurrentFromHW()) {
return; // no result, continue to wait
}
// found value, advance at least one track
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// for scope debug track[1]->setBrake(0);
waiting = false;
tr++;
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if (tr > lastTrack) tr = 0;
if (lastTrack < 2 || track[tr]->getMode() & TRACK_MODE_PROG) {
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return; // We could continue but for prog track we
// rather do it in next interrupt beacuse
// that gives us well defined sampling point.
// For other tracks we care less unless we
// have only few (max 2) tracks.
}
}
if (!waiting) {
// look for a valid track to sample or until we are around
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while (true) {
if (track[tr]->getMode() & ( TRACK_MODE_MAIN|TRACK_MODE_PROG|TRACK_MODE_DC|TRACK_MODE_DCX|TRACK_MODE_EXT )) {
track[tr]->startCurrentFromHW();
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// for scope debug track[1]->setBrake(1);
waiting = true;
break;
}
tr++;
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if (tr > lastTrack) tr = 0;
if (tr == trAtStart) // we are through and nothing found to do
return;
}
}
}
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#endif
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// The setup call is done this way so that the tracks can be in a list
// from the config... the tracks default to NULL in the declaration
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void TrackManager::Setup(const FSH * shieldname,
MotorDriver * track0, MotorDriver * track1, MotorDriver * track2,
MotorDriver * track3, MotorDriver * track4, MotorDriver * track5,
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MotorDriver * track6, MotorDriver * track7 ) {
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addTrack(0,track0);
addTrack(1,track1);
addTrack(2,track2);
addTrack(3,track3);
addTrack(4,track4);
addTrack(5,track5);
addTrack(6,track6);
addTrack(7,track7);
// Default the first 2 tracks (which may be null) and perform HA waveform check.
setTrackMode(0,TRACK_MODE_MAIN);
#ifndef DISABLE_PROG
setTrackMode(1,TRACK_MODE_PROG);
#else
setTrackMode(1,TRACK_MODE_MAIN);
#endif
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// Fault pin config for odd motor boards (example pololu)
FOR_EACH_TRACK(t) {
for (byte s=t+1;s<=lastTrack;s++) {
if (track[t]->getFaultPin() != UNUSED_PIN &&
track[t]->getFaultPin() == track[s]->getFaultPin()) {
track[t]->setCommonFaultPin();
track[s]->setCommonFaultPin();
DIAG(F("Common Fault pin tracks %c and %c"), t+'A', s+'A');
}
}
}
DCC::setShieldName(shieldname);
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}
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void TrackManager::addTrack(byte t, MotorDriver* driver) {
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track[t]=driver;
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if (driver) {
track[t]->setPower(POWERMODE::OFF);
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track[t]->setMode(TRACK_MODE_NONE);
track[t]->setTrackLetter('A'+t);
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lastTrack=t;
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}
}
// setDCCSignal(), called from interrupt context
// does assume ports are shadowed if they can be
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void TrackManager::setDCCSignal( bool on) {
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HAVE_PORTA(shadowPORTA=PORTA);
HAVE_PORTB(shadowPORTB=PORTB);
HAVE_PORTC(shadowPORTC=PORTC);
APPLY_BY_MODE(TRACK_MODE_MAIN,setSignal(on));
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HAVE_PORTA(PORTA=shadowPORTA);
HAVE_PORTB(PORTB=shadowPORTB);
HAVE_PORTC(PORTC=shadowPORTC);
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}
void TrackManager::setCutout( bool on) {
(void) on;
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// TODO Cutout needs fake ports as well
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// TODO APPLY_BY_MODE(TRACK_MODE_MAIN,setCutout(on));
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}
// setPROGSignal(), called from interrupt context
// does assume ports are shadowed if they can be
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void TrackManager::setPROGSignal( bool on) {
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HAVE_PORTA(shadowPORTA=PORTA);
HAVE_PORTB(shadowPORTB=PORTB);
HAVE_PORTC(shadowPORTC=PORTC);
APPLY_BY_MODE(TRACK_MODE_PROG,setSignal(on));
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HAVE_PORTA(PORTA=shadowPORTA);
HAVE_PORTB(PORTB=shadowPORTB);
HAVE_PORTC(PORTC=shadowPORTC);
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}
// setDCSignal(), called from normal context
// MotorDriver::setDCSignal handles shadowed IO port changes.
// with interrupts turned off around the critical section
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void TrackManager::setDCSignal(int16_t cab, byte speedbyte) {
FOR_EACH_TRACK(t) {
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if (trackDCAddr[t]!=cab && cab != 0) continue;
if (track[t]->getMode()==TRACK_MODE_DC) track[t]->setDCSignal(speedbyte);
else if (track[t]->getMode()==TRACK_MODE_DCX) track[t]->setDCSignal(speedbyte ^ 128);
}
}
bool TrackManager::setTrackMode(byte trackToSet, TRACK_MODE mode, int16_t dcAddr) {
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if (trackToSet>lastTrack || track[trackToSet]==NULL) return false;
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//DIAG(F("Track=%c Mode=%d"),trackToSet+'A', mode);
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// DC tracks require a motorDriver that can set brake!
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if (mode==TRACK_MODE_DC || mode==TRACK_MODE_DCX) {
#if defined(ARDUINO_AVR_UNO)
DIAG(F("Uno has no PWM timers available for DC"));
return false;
#endif
if (!track[trackToSet]->brakeCanPWM()) {
DIAG(F("Brake pin can't PWM: No DC"));
return false;
}
}
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#ifdef ARDUINO_ARCH_ESP32
// remove pin from MUX matrix and turn it off
pinpair p = track[trackToSet]->getSignalPin();
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//DIAG(F("Track=%c remove pin %d"),trackToSet+'A', p.pin);
gpio_reset_pin((gpio_num_t)p.pin);
pinMode(p.pin, OUTPUT); // gpio_reset_pin may reset to input
if (p.invpin != UNUSED_PIN) {
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//DIAG(F("Track=%c remove ^pin %d"),trackToSet+'A', p.invpin);
gpio_reset_pin((gpio_num_t)p.invpin);
pinMode(p.invpin, OUTPUT); // gpio_reset_pin may reset to input
}
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#endif
#ifndef DISABLE_PROG
if (mode==TRACK_MODE_PROG) {
#else
if (false) {
#endif
// only allow 1 track to be prog
FOR_EACH_TRACK(t)
if (track[t]->getMode()==TRACK_MODE_PROG && t != trackToSet) {
track[t]->setPower(POWERMODE::OFF);
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track[t]->setMode(TRACK_MODE_NONE);
track[t]->makeProgTrack(false); // revoke prog track special handling
streamTrackState(NULL,t);
}
track[trackToSet]->makeProgTrack(true); // set for prog track special handling
} else {
track[trackToSet]->makeProgTrack(false); // only the prog track knows it's type
}
track[trackToSet]->setMode(mode);
trackDCAddr[trackToSet]=dcAddr;
streamTrackState(NULL,trackToSet);
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// When a track is switched, we must clear any side effects of its previous
// state, otherwise trains run away or just dont move.
// This can be done BEFORE the PWM-Timer evaluation (methinks)
if (!(mode==TRACK_MODE_DC || mode==TRACK_MODE_DCX)) {
// DCC tracks need to have set the PWM to zero or they will not work.
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track[trackToSet]->detachDCSignal();
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track[trackToSet]->setBrake(false);
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}
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// EXT is a special case where the signal pin is
// turned off. So unless that is set, the signal
// pin should be turned on
track[trackToSet]->enableSignal(mode != TRACK_MODE_EXT);
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#ifndef ARDUINO_ARCH_ESP32
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// re-evaluate HighAccuracy mode
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// We can only do this is all main and prog tracks agree
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bool canDo=true;
FOR_EACH_TRACK(t) {
// DC tracks must not have the DCC PWM switched on
// so we globally turn it off if one of the PWM
// capable tracks is now DC or DCX.
if (track[t]->getMode()==TRACK_MODE_DC || track[t]->getMode()==TRACK_MODE_DCX) {
if (track[t]->isPWMCapable()) {
canDo=false; // this track is capable but can not run PWM
break; // in this mode, so abort and prevent globally below
} else {
track[t]->trackPWM=false; // this track sure can not run with PWM
//DIAG(F("Track %c trackPWM 0 (not capable)"), t+'A');
}
} else if (track[t]->getMode()==TRACK_MODE_MAIN || track[t]->getMode()==TRACK_MODE_PROG) {
track[t]->trackPWM = track[t]->isPWMCapable(); // trackPWM is still a guess here
//DIAG(F("Track %c trackPWM %d"), t+'A', track[t]->trackPWM);
canDo &= track[t]->trackPWM;
}
}
if (!canDo) {
// if we discover that HA mode was globally impossible
// we must adjust the trackPWM capabilities
FOR_EACH_TRACK(t) {
track[t]->trackPWM=false;
//DIAG(F("Track %c trackPWM 0 (global override)"), t+'A');
}
DCCTimer::clearPWM(); // has to be AFTER trackPWM changes because if trackPWM==true this is undone for that track
}
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#else
// For ESP32 we just reinitialize the DCC Waveform
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DCCWaveform::begin();
#endif
// This block must be AFTER the PWM-Timer modifications
if (mode==TRACK_MODE_DC || mode==TRACK_MODE_DCX) {
// DC tracks need to be given speed of the throttle for that cab address
// otherwise will not match other tracks on same cab.
// This also needs to allow for inverted DCX
applyDCSpeed(trackToSet);
}
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// Normal running tracks are set to the global power state
track[trackToSet]->setPower(
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(mode==TRACK_MODE_MAIN || mode==TRACK_MODE_DC || mode==TRACK_MODE_DCX || mode==TRACK_MODE_EXT) ?
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mainPowerGuess : POWERMODE::OFF);
//DIAG(F("TrackMode=%d"),mode);
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return true;
}
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void TrackManager::applyDCSpeed(byte t) {
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uint8_t speedByte=DCC::getThrottleSpeedByte(trackDCAddr[t]);
if (track[t]->getMode()==TRACK_MODE_DCX)
speedByte = speedByte ^ 128; // reverse direction bit
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track[t]->setDCSignal(speedByte);
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}
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bool TrackManager::parseJ(Print *stream, int16_t params, int16_t p[])
{
if (params==0) { // <=> List track assignments
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FOR_EACH_TRACK(t)
streamTrackState(stream,t);
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return true;
}
p[0]-=HASH_KEYWORD_A; // convert A... to 0....
if (params>1 && (p[0]<0 || p[0]>=MAX_TRACKS))
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return false;
if (params==2 && p[1]==HASH_KEYWORD_MAIN) // <= id MAIN>
return setTrackMode(p[0],TRACK_MODE_MAIN);
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#ifndef DISABLE_PROG
if (params==2 && p[1]==HASH_KEYWORD_PROG) // <= id PROG>
return setTrackMode(p[0],TRACK_MODE_PROG);
#endif
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if (params==2 && (p[1]==HASH_KEYWORD_OFF || p[1]==HASH_KEYWORD_NONE)) // <= id OFF> <= id NONE>
return setTrackMode(p[0],TRACK_MODE_NONE);
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if (params==2 && p[1]==HASH_KEYWORD_EXT) // <= id EXT>
return setTrackMode(p[0],TRACK_MODE_EXT);
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if (params==3 && p[1]==HASH_KEYWORD_DC && p[2]>0) // <= id DC cab>
return setTrackMode(p[0],TRACK_MODE_DC,p[2]);
if (params==3 && p[1]==HASH_KEYWORD_DCX && p[2]>0) // <= id DCX cab>
return setTrackMode(p[0],TRACK_MODE_DCX,p[2]);
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return false;
}
void TrackManager::streamTrackState(Print* stream, byte t) {
// null stream means send to commandDistributor for broadcast
if (track[t]==NULL) return;
auto format=F("");
switch(track[t]->getMode()) {
case TRACK_MODE_MAIN:
format=F("<= %c MAIN>\n");
break;
#ifndef DISABLE_PROG
case TRACK_MODE_PROG:
format=F("<= %c PROG>\n");
break;
#endif
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case TRACK_MODE_NONE:
format=F("<= %c NONE>\n");
break;
case TRACK_MODE_EXT:
format=F("<= %c EXT>\n");
break;
case TRACK_MODE_DC:
format=F("<= %c DC %d>\n");
break;
case TRACK_MODE_DCX:
format=F("<= %c DCX %d>\n");
break;
default:
break; // unknown, dont care
}
if (stream) StringFormatter::send(stream,format,'A'+t,trackDCAddr[t]);
else CommandDistributor::broadcastTrackState(format,'A'+t,trackDCAddr[t]);
}
byte TrackManager::nextCycleTrack=MAX_TRACKS;
void TrackManager::loop() {
DCCWaveform::loop();
#ifndef DISABLE_PROG
DCCACK::loop();
#endif
bool dontLimitProg=DCCACK::isActive() || progTrackSyncMain || progTrackBoosted;
nextCycleTrack++;
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if (nextCycleTrack>lastTrack) nextCycleTrack=0;
if (track[nextCycleTrack]==NULL) return;
MotorDriver * motorDriver=track[nextCycleTrack];
bool useProgLimit=dontLimitProg? false: track[nextCycleTrack]->getMode()==TRACK_MODE_PROG;
motorDriver->checkPowerOverload(useProgLimit, nextCycleTrack);
}
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MotorDriver * TrackManager::getProgDriver() {
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FOR_EACH_TRACK(t)
if (track[t]->getMode()==TRACK_MODE_PROG) return track[t];
return NULL;
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}
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#ifdef ARDUINO_ARCH_ESP32
std::vector<MotorDriver *>TrackManager::getMainDrivers() {
std::vector<MotorDriver *> v;
FOR_EACH_TRACK(t)
if (track[t]->getMode()==TRACK_MODE_MAIN) v.push_back(track[t]);
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return v;
}
#endif
void TrackManager::setPower2(bool setProg,POWERMODE mode) {
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if (!setProg) mainPowerGuess=mode;
FOR_EACH_TRACK(t) {
MotorDriver * driver=track[t];
if (!driver) continue;
switch (track[t]->getMode()) {
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case TRACK_MODE_MAIN:
if (setProg) break;
// toggle brake before turning power on - resets overcurrent error
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// on the Pololu board if brake is wired to ^D2.
// XXX see if we can make this conditional
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driver->setBrake(true);
driver->setBrake(false); // DCC runs with brake off
driver->setPower(mode);
break;
case TRACK_MODE_DC:
case TRACK_MODE_DCX:
if (setProg) break;
driver->setBrake(true); // DC starts with brake on
applyDCSpeed(t); // speed match DCC throttles
driver->setPower(mode);
break;
case TRACK_MODE_PROG:
if (!setProg) break;
driver->setBrake(true);
driver->setBrake(false);
driver->setPower(mode);
break;
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case TRACK_MODE_EXT:
driver->setBrake(true);
driver->setBrake(false);
driver->setPower(mode);
break;
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case TRACK_MODE_NONE:
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break;
}
}
}
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POWERMODE TrackManager::getProgPower() {
FOR_EACH_TRACK(t)
if (track[t]->getMode()==TRACK_MODE_PROG)
return track[t]->getPower();
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return POWERMODE::OFF;
}
void TrackManager::reportObsoleteCurrent(Print* stream) {
// This function is for backward JMRI compatibility only
// It reports the first track only, as main, regardless of track settings.
// <c MeterName value C/V unit min max res warn>
int maxCurrent=track[0]->raw2mA(track[0]->getRawCurrentTripValue());
StringFormatter::send(stream, F("<c CurrentMAIN %d C Milli 0 %d 1 %d>\n"),
track[0]->raw2mA(track[0]->getCurrentRaw(false)), maxCurrent, maxCurrent);
}
void TrackManager::reportCurrent(Print* stream) {
StringFormatter::send(stream,F("<jI"));
FOR_EACH_TRACK(t) {
StringFormatter::send(stream, F(" %d"),
(track[t]->getPower()==POWERMODE::OVERLOAD) ? -1 :
track[t]->raw2mA(track[t]->getCurrentRaw(false)));
}
StringFormatter::send(stream,F(">\n"));
}
void TrackManager::reportGauges(Print* stream) {
StringFormatter::send(stream,F("<jG"));
FOR_EACH_TRACK(t) {
StringFormatter::send(stream, F(" %d"),
track[t]->raw2mA(track[t]->getRawCurrentTripValue()));
}
StringFormatter::send(stream,F(">\n"));
}
void TrackManager::setJoinRelayPin(byte joinRelayPin) {
joinRelay=joinRelayPin;
if (joinRelay!=UNUSED_PIN) {
pinMode(joinRelay,OUTPUT);
digitalWrite(joinRelay,LOW); // LOW is relay disengaged
}
}
void TrackManager::setJoin(bool joined) {
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#ifdef ARDUINO_ARCH_ESP32
if (joined) {
FOR_EACH_TRACK(t) {
if (track[t]->getMode()==TRACK_MODE_PROG) {
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tempProgTrack = t;
setTrackMode(t, TRACK_MODE_MAIN);
break;
}
}
} else {
if (tempProgTrack != MAX_TRACKS+1) {
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// as setTrackMode with TRACK_MODE_PROG defaults to
// power off, we will take the current power state
// of our track and then preserve that state.
POWERMODE tPTmode = track[tempProgTrack]->getPower(); //get current power status of this track
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setTrackMode(tempProgTrack, TRACK_MODE_PROG);
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track[tempProgTrack]->setPower(tPTmode); //set track status as it was before
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tempProgTrack = MAX_TRACKS+1;
}
}
#endif
progTrackSyncMain=joined;
if (joinRelay!=UNUSED_PIN) digitalWrite(joinRelay,joined?HIGH:LOW);
}
bool TrackManager::isPowerOn(byte t) {
if (track[t]->getPower()!=POWERMODE::ON)
return false;
return true;
}