Merge 183b824a5d into 27a5f76a8d

Merge pull request #361 from DCC-EX:separate-hal-extt-turntable
Separate-hal-extt-turntable
2024-11-24 16:46:13 +01:00 · 2023-10-20 23:46:29 +08:00 · 2023-10-17 05:17:24 +10:00 · 2023-10-17 05:08:04 +10:00 · 2023-10-17 05:06:35 +10:00 · 2023-10-16 08:12:11 +10:00
59 changed files with 4180 additions and 1023 deletions
--- a/.gitignore
+++ b/.gitignore
@ -13,3 +13,5 @@ myFilter.cpp
 my*.h
 !my*.example.h
 compile_commands.json
 newcode.txt.old
 UserAddin.txt
--- a/CommandDistributor.cpp
+++ b/CommandDistributor.cpp
@ -2,6 +2,7 @@
 *  © 2022 Harald Barth
 *  © 2020-2021 Chris Harlow
 *  © 2020 Gregor Baues
 *  © 2022 Colin Murdoch
 *  All rights reserved.
 *
 *  This file is part of CommandStation-EX
@ -160,6 +161,10 @@ void  CommandDistributor::broadcastTurnout(int16_t id, bool isClosed ) {
 #endif
 }
 void CommandDistributor::broadcastTurntable(int16_t id, uint8_t position, bool moving) {
  broadcastReply(COMMAND_TYPE, F("<I %d %d %d>\n"), id, position, moving);
 }
 void  CommandDistributor::broadcastClockTime(int16_t time, int8_t rate) {
  // The JMRI clock command is of the form : PFT65871<;>4
  // The CS broadcast is of the form "<jC mmmm nn" where mmmm is time minutes and dd speed
@ -167,7 +172,7 @@ void  CommandDistributor::broadcastClockTime(int16_t time, int8_t rate) {
  // be safe for both types.
  broadcastReply(COMMAND_TYPE, F("<jC %d %d>\n"),time, rate);
 #ifdef CD_HANDLE_RING
-  broadcastReply(WITHROTTLE_TYPE, F("PFT%d<;>%d\n"), time*60, rate);
+  broadcastReply(WITHROTTLE_TYPE, F("PFT%l<;>%d\n"), (int32_t)time*60, rate);
 #endif
 }
@ -204,6 +209,39 @@ int16_t CommandDistributor::retClockTime() {
 void  CommandDistributor::broadcastLoco(byte slot) {
  DCC::LOCO * sp=&DCC::speedTable[slot];
  broadcastReply(COMMAND_TYPE, F("<l %d %d %d %l>\n"), sp->loco,slot,sp->speedCode,sp->functions);
 #ifdef SABERTOOTH
  if (Serial2 && sp->loco == SABERTOOTH) {
    static uint8_t rampingmode = 0;
    bool direction = (sp->speedCode & 0x80) !=0; // true for forward
    int32_t speed = sp->speedCode & 0x7f;
    if (speed == 1) { // emergency stop
      if (rampingmode != 1) {
 	rampingmode = 1;
 	Serial2.print("R1: 0\r\n");
 	Serial2.print("R2: 0\r\n");
      }
      Serial2.print("MD: 0\r\n");
    } else {
      if (speed != 0) {
        // speed is here 2 to 127
 	speed = (speed - 1) * 1625 / 100;
 	speed = speed * (direction ? 1 : -1);
 	// speed is here -2047 to 2047
      }
      if (rampingmode != 2) {
 	rampingmode = 2;
 	Serial2.print("R1: 2047\r\n");
 	Serial2.print("R2: 2047\r\n");
      }
      Serial2.print("M1: ");
      Serial2.print(speed);
      Serial2.print("\r\n");
      Serial2.print("M2: ");
      Serial2.print(speed);
      Serial2.print("\r\n");
    }
  }
 #endif
 #ifdef CD_HANDLE_RING
  WiThrottle::markForBroadcast(sp->loco);
 #endif
@ -227,13 +265,10 @@ void  CommandDistributor::broadcastPower() {
  LCD(2,F("Power %S%S"),state=='1'?F("On"):F("Off"),reason);  
 }
-void CommandDistributor::broadcastText(const FSH * msg) {
+void CommandDistributor::broadcastRaw(clientType type, char * msg) {
-  broadcastReply(COMMAND_TYPE, F("<I %S>\n"),msg);
+  broadcastReply(type, F("%s"),msg);
 #ifdef CD_HANDLE_RING
  broadcastReply(WITHROTTLE_TYPE, F("Hm%S\n"), msg);
 #endif
 }
-void CommandDistributor::broadcastTrackState(const FSH* format,byte trackLetter,int16_t dcAddr) {
+void CommandDistributor::broadcastTrackState(const FSH* format,byte trackLetter, int16_t dcAddr) {
-  broadcastReply(COMMAND_TYPE, format,trackLetter,dcAddr);
+  broadcastReply(COMMAND_TYPE, format,trackLetter, dcAddr);
 }
--- a/CommandDistributor.h
+++ b/CommandDistributor.h
@ -2,6 +2,8 @@
 *  © 2022 Harald Barth
 *  © 2020-2021 Chris Harlow
 *  © 2020 Gregor Baues
 *  © 2022 Colin Murdoch
 * 
 *  All rights reserved.
 *
 *  This file is part of CommandStation-EX
@ -33,8 +35,9 @@
 #endif 
 class CommandDistributor {
-private:
+public:
  enum clientType: byte {NONE_TYPE,COMMAND_TYPE,WITHROTTLE_TYPE};
 private:
  static void broadcastToClients(clientType type);
  static StringBuffer * broadcastBufferWriter;
  #ifdef CD_HANDLE_RING
@ -46,12 +49,13 @@ public :
  static void broadcastLoco(byte slot);
  static void broadcastSensor(int16_t id, bool value);
  static void broadcastTurnout(int16_t id, bool isClosed);
  static void broadcastTurntable(int16_t id, uint8_t position, bool moving);
  static void broadcastClockTime(int16_t time, int8_t rate);
  static void setClockTime(int16_t time, int8_t rate, byte opt);
  static int16_t retClockTime();
  static void broadcastPower();
-  static void broadcastText(const FSH * msg);
+  static void broadcastRaw(clientType type,char * msg);
-  static void broadcastTrackState(const FSH* format,byte trackLetter,int16_t dcAddr);
+  static void broadcastTrackState(const FSH* format,byte trackLetter, int16_t dcAddr);
  template<typename... Targs> static void broadcastReply(clientType type, Targs... msg);
  static void forget(byte clientId);
--- a/CommandStation-EX.ino
+++ b/CommandStation-EX.ino
@ -30,6 +30,7 @@
 *  © 2021 Neil McKechnie
 *  © 2020-2021 Chris Harlow, Harald Barth, David Cutting,
 *  Fred Decker, Gregor Baues, Anthony W - Dayton
 *  © 2023 Nathan Kellenicki
 *  All rights reserved.
 *
 *  This file is part of CommandStation-EX
@ -78,6 +79,12 @@ void setup()
 // Initialise HAL layer before reading EEprom or setting up MotorDrivers 
  IODevice::begin();
  // As the setup of a motor shield may require a read of the current sense input from the ADC,
  // let's make sure to initialise the ADCee class!
  ADCee::begin();
  // Set up MotorDrivers early to initialize all pins
  TrackManager::Setup(MOTOR_SHIELD_TYPE);
  DISPLAY_START (
    // This block is still executed for DIAGS if display not in use
    LCD(0,F("DCC-EX v%S"),F(VERSION));
@ -89,26 +96,19 @@ void setup()
  // Start Ethernet if it exists
 #ifndef ARDUINO_ARCH_ESP32
 #if WIFI_ON
-  WifiInterface::setup(WIFI_SERIAL_LINK_SPEED, F(WIFI_SSID), F(WIFI_PASSWORD), F(WIFI_HOSTNAME), IP_PORT, WIFI_CHANNEL);
+  WifiInterface::setup(WIFI_SERIAL_LINK_SPEED, F(WIFI_SSID), F(WIFI_PASSWORD), F(WIFI_HOSTNAME), IP_PORT, WIFI_CHANNEL, WIFI_FORCE_AP);
 #endif // WIFI_ON
 #else
  // ESP32 needs wifi on always
-  WifiESP::setup(WIFI_SSID, WIFI_PASSWORD, WIFI_HOSTNAME, IP_PORT, WIFI_CHANNEL);
+  WifiESP::setup(WIFI_SSID, WIFI_PASSWORD, WIFI_HOSTNAME, IP_PORT, WIFI_CHANNEL, WIFI_FORCE_AP);
 #endif // ARDUINO_ARCH_ESP32
 #if ETHERNET_ON
  EthernetInterface::setup();
 #endif // ETHERNET_ON
  // As the setup of a motor shield may require a read of the current sense input from the ADC,
  // let's make sure to initialise the ADCee class!
  ADCee::begin();
  // Responsibility 3: Start the DCC engine.
-  // Note: this provides DCC with two motor drivers, main and prog, which handle the motor shield(s)
+  DCC::begin();
  // Standard supported devices have pre-configured macros but custome hardware installations require
  //  detailed pin mappings and may also require modified subclasses of the MotorDriver to implement specialist logic.
  // STANDARD_MOTOR_SHIELD, POLOLU_MOTOR_SHIELD, FIREBOX_MK1, FIREBOX_MK1S are pre defined in MotorShields.h
  TrackManager::Setup(MOTOR_SHIELD_TYPE);
  // Start RMFT aka EX-RAIL (ignored if no automnation)
  RMFT::begin();
--- a/DCC.cpp
+++ b/DCC.cpp
@ -60,8 +60,7 @@ const byte FN_GROUP_5=0x10;
 FSH* DCC::shieldName=NULL;
 byte DCC::globalSpeedsteps=128;
-void DCC::begin(const FSH * motorShieldName) {
+void DCC::begin() {
  shieldName=(FSH *)motorShieldName;
  StringFormatter::send(&USB_SERIAL,F("<iDCC-EX V-%S / %S / %S G-%S>\n"), F(VERSION), F(ARDUINO_TYPE), shieldName, F(GITHUB_SHA));
 #ifndef DISABLE_EEPROM
  // Load stuff from EEprom
@ -693,7 +692,7 @@ void  DCC::updateLocoReminder(int loco, byte speedCode) {
  if (loco==0) {
     // broadcast stop/estop but dont change direction
-     for (int reg = 0; reg < highestUsedReg; reg++) {
+     for (int reg = 0; reg <= highestUsedReg; reg++) {
       if (speedTable[reg].loco==0) continue;
       byte newspeed=(speedTable[reg].speedCode & 0x80) |  (speedCode & 0x7f);
       if (speedTable[reg].speedCode != newspeed) {
--- a/DCC.h
+++ b/DCC.h
@ -51,7 +51,10 @@ const byte MAX_LOCOS = 30;
 class DCC
 {
 public:
-  static void begin(const FSH * motorShieldName);
+  static inline void setShieldName(const FSH * motorShieldName) {
    shieldName=(FSH *)motorShieldName;
  };
  static void begin();
  static void loop();
  // Public DCC API functions
--- a/DCCACK.cpp
+++ b/DCCACK.cpp
@ -152,7 +152,7 @@ byte DCCACK::getAck() {
      return(0);  // pending set off but not detected means no ACK.   
 }
-
+#ifndef DISABLE_PROG
 void DCCACK::loop() {
  while (ackManagerProg) {
    byte opcode=GETFLASH(ackManagerProg);
@ -351,7 +351,7 @@ void DCCACK::callback(int value) {
    switch (callbackState) {
      case AFTER_READ:
-         if (ackManagerRejoin && autoPowerOff) {
+         if (ackManagerRejoin && !autoPowerOff) {
                progDriver->setPower(POWERMODE::OFF);
                callbackStart=millis();
                callbackState=WAITING_30;
@ -414,7 +414,7 @@ void DCCACK::callback(int value) {
          (ackManagerCallback)( value);
    }
 }
-
+#endif
 void DCCACK::checkAck(byte sentResetsSincePacket) {
    if (!ackPending) return; 
--- a/DCCEXParser.cpp
+++ b/DCCEXParser.cpp
@ -3,10 +3,11 @@
 *  © 2021 Neil McKechnie
 *  © 2021 Mike S
 *  © 2021 Herb Morton
- *  © 2020-2022 Harald Barth
+ *  © 2020-2023 Harald Barth
 *  © 2020-2021 M Steve Todd
 *  © 2020-2021 Fred Decker
 *  © 2020-2021 Chris Harlow
 *  © 2022 Colin Murdoch
 *  All rights reserved.
 *  
 *  This file is part of CommandStation-EX
@ -24,6 +25,79 @@
 *  You should have received a copy of the GNU General Public License
 *  along with CommandStation.  If not, see <https://www.gnu.org/licenses/>.
 */
 /*
 List of single character OPCODEs in use for reference.
 When determining a new OPCODE for a new feature, refer to this list as the source of truth.
 Once a new OPCODE is decided upon, update this list.
  Character, Usage
  /, |EX-R| interactive commands
  -, Remove from reminder table
  =, |TM| configuration
  !, Emergency stop
  @, Reserved for future use - LCD messages to JMRI
  #, Request number of supported cabs/locos; heartbeat
  +, WiFi AT commands
  ?, Reserved for future use
  0, Track power off
  1, Track power on
  a, DCC accessory control
  A,
  b, Write CV bit on main
  B, Write CV bit
  c, Request current command
  C,
  d,
  D, Diagnostic commands
  e, Erase EEPROM
  E, Store configuration in EEPROM
  f, Loco decoder function control (deprecated)
  F, Loco decoder function control
  g,
  G,
  h,
  H, Turnout state broadcast
  i, Server details string
  I, Turntable object command, control, and broadcast
  j, Throttle responses
  J, Throttle queries
  k, Reserved for future use - Potentially Railcom
  K, Reserved for future use - Potentially Railcom
  l, Loco speedbyte/function map broadcast
  L, Reserved for LCC interface (implemented in EXRAIL)
  m,
  M, Write DCC packet
  n,
  N,
  o,
  O, Output broadcast
  p, Broadcast power state
  P, Write DCC packet
  q, Sensor deactivated
  Q, Sensor activated
  r, Broadcast address read on programming track
  R, Read CVs
  s, Display status
  S, Sensor configuration
  t, Cab/loco update command
  T, Turnout configuration/control
  u, Reserved for user commands
  U, Reserved for user commands
  v,
  V, Verify CVs
  w, Write CV on main
  W, Write CV
  x,
  X, Invalid command
  y,
  Y, Output broadcast
  z,
  Z, Output configuration/control
 */
 #include "StringFormatter.h"
 #include "DCCEXParser.h"
 #include "DCC.h"
@ -40,22 +114,21 @@
 #include "TrackManager.h"
 #include "DCCTimer.h"
 #include "EXRAIL2.h"
 #include "Turntables.h"
 // This macro can't be created easily as a portable function because the
 // flashlist requires a far pointer for high flash access. 
 #define SENDFLASHLIST(stream,flashList)                 \
    for (int16_t i=0;;i+=sizeof(flashList[0])) {                            \
        int16_t value=GETHIGHFLASHW(flashList,i);       \
-        if (value==0) break;                            \
+        if (value==INT16_MAX) break;                            \
-        StringFormatter::send(stream,F(" %d"),value);   \
+        StringFormatter::send(stream,F(" %d"),value);	\
    }                                   
 // These keywords are used in the <1> command. The number is what you get if you use the keyword as a parameter.
 // To discover new keyword numbers , use the <$ YOURKEYWORD> command
 const int16_t HASH_KEYWORD_PROG = -29718;
 const int16_t HASH_KEYWORD_MAIN = 11339;
 const int16_t HASH_KEYWORD_JOIN = -30750;
 const int16_t HASH_KEYWORD_CABS = -11981;
 const int16_t HASH_KEYWORD_RAM = 25982;
 const int16_t HASH_KEYWORD_CMD = 9962;
@ -63,7 +136,11 @@ const int16_t HASH_KEYWORD_ACK = 3113;
 const int16_t HASH_KEYWORD_ON = 2657;
 const int16_t HASH_KEYWORD_DCC = 6436;
 const int16_t HASH_KEYWORD_SLOW = -17209;
 #ifndef DISABLE_PROG
 const int16_t HASH_KEYWORD_JOIN = -30750;
 const int16_t HASH_KEYWORD_PROG = -29718;
 const int16_t HASH_KEYWORD_PROGBOOST = -6353;
 #endif
 #ifndef DISABLE_EEPROM
 const int16_t HASH_KEYWORD_EEPROM = -7168;
 #endif
@ -80,7 +157,10 @@ const int16_t HASH_KEYWORD_VPIN=-415;
 const int16_t HASH_KEYWORD_A='A';
 const int16_t HASH_KEYWORD_C='C';
 const int16_t HASH_KEYWORD_G='G';
 const int16_t HASH_KEYWORD_H='H';
 const int16_t HASH_KEYWORD_I='I';
 const int16_t HASH_KEYWORD_O='O';
 const int16_t HASH_KEYWORD_P='P';
 const int16_t HASH_KEYWORD_R='R';
 const int16_t HASH_KEYWORD_T='T';
 const int16_t HASH_KEYWORD_X='X';
@ -92,6 +172,8 @@ const int16_t HASH_KEYWORD_ANOUT = -26399;
 const int16_t HASH_KEYWORD_WIFI = -5583;
 const int16_t HASH_KEYWORD_ETHERNET = -30767;
 const int16_t HASH_KEYWORD_WIT = 31594;
 const int16_t HASH_KEYWORD_EXTT = 8573;
 const int16_t HASH_KEYWORD_ADD = 3201;
 int16_t DCCEXParser::stashP[MAX_COMMAND_PARAMS];
 bool DCCEXParser::stashBusy;
@ -216,6 +298,9 @@ void DCCEXParser::parse(Print *stream,  byte *com,  RingStream *ringStream) {
 void DCCEXParser::parseOne(Print *stream, byte *com, RingStream * ringStream)
 {
 #ifdef DISABLE_PROG
    (void)ringStream;
 #endif
 #ifndef DISABLE_EEPROM
    (void)EEPROM; // tell compiler not to warn this is unused
 #endif
@ -285,6 +370,8 @@ void DCCEXParser::parseOne(Print *stream, byte *com, RingStream * ringStream)
        if (direction < 0 || direction > 1)
            break; // invalid direction code
 	if (cab > 10239 || cab < 0)
 	    break; // beyond DCC range
        DCC::setThrottle(cab, tspeed, direction);
        if (params == 4) // send obsolete format T response
@ -368,16 +455,24 @@ void DCCEXParser::parseOne(Print *stream, byte *com, RingStream * ringStream)
            return;
        break;
 #ifndef DISABLE_PROG
    case 'w': // WRITE CV on MAIN <w CAB CV VALUE>
-        DCC::writeCVByteMain(p[0], p[1], p[2]);
+      if (params != 3)
-        return;
+	break;
      DCC::writeCVByteMain(p[0], p[1], p[2]);
      return;
    case 'b': // WRITE CV BIT ON MAIN <b CAB CV BIT VALUE>
-        DCC::writeCVBitMain(p[0], p[1], p[2], p[3]);
+      if (params != 4)
-        return;
+	break;
      DCC::writeCVBitMain(p[0], p[1], p[2], p[3]);
      return;
 #endif
    case 'M': // WRITE TRANSPARENT DCC PACKET MAIN <M REG X1 ... X9>
 #ifndef DISABLE_PROG
    case 'P': // WRITE TRANSPARENT DCC PACKET PROG <P REG X1 ... X9>
 #endif
        // NOTE: this command was parsed in HEX instead of decimal
        params--; // drop REG
        if (params<1) break;
@ -392,15 +487,18 @@ void DCCEXParser::parseOne(Print *stream, byte *com, RingStream * ringStream)
        }
        return;
 #ifndef DISABLE_PROG
    case 'W': // WRITE CV ON PROG <W CV VALUE CALLBACKNUM CALLBACKSUB>
-            if (!stashCallback(stream, p, ringStream))
+        if (!stashCallback(stream, p, ringStream))
-                break;
+	    break;
        if (params == 1) // <W id> Write new loco id (clearing consist and managing short/long)
            DCC::setLocoId(p[0],callback_Wloco);
        else if (params == 4)  // WRITE CV ON PROG <W CV VALUE [CALLBACKNUM] [CALLBACKSUB]>
            DCC::writeCVByte(p[0], p[1], callback_W4);
-        else  // WRITE CV ON PROG <W CV VALUE>
+        else if (params == 2)  // WRITE CV ON PROG <W CV VALUE>
            DCC::writeCVByte(p[0], p[1], callback_W);
 	else
            break;
        return;
    case 'V': // VERIFY CV ON PROG <V CV VALUE> <V CV BIT 0|1>
@ -420,9 +518,11 @@ void DCCEXParser::parseOne(Print *stream, byte *com, RingStream * ringStream)
        }
        break;
-    case 'B': // WRITE CV BIT ON PROG <B CV BIT VALUE CALLBACKNUM CALLBACKSUB>
+    case 'B': // WRITE CV BIT ON PROG  <B CV BIT VALUE CALLBACKNUM CALLBACKSUB> or <B CV BIT VALUE>
        if (params != 3 && params != 5)
 	  break;
        if (!stashCallback(stream, p, ringStream))
-            break;
+	  break;
        DCC::writeCVBit(p[0], p[1], p[2], callback_B);
        return;
@ -449,68 +549,135 @@ void DCCEXParser::parseOne(Print *stream, byte *com, RingStream * ringStream)
            return;
        }
        break;
 #endif
    case '1': // POWERON <1   [MAIN|PROG|JOIN]>
        {
-        bool main=false;
+            bool main=false;
-        bool prog=false;
+            bool prog=false;
-        bool join=false;
+            bool join=false;
-        if (params > 1) break;
+            bool singletrack=false;
-        if (params==0 || MotorDriver::commonFaultPin) { // <1> or tracks can not be handled individually
+            //byte t=0;
-            main=true;
+            if (params > 1) break;
-            prog=true;
+            if (params==0) { // All
-        }
+                main=true;
-	if (params==1) {
+                prog=true;
-	  if (p[0] == HASH_KEYWORD_JOIN) {  // <1 JOIN>
+            }
-            main=true;
+            if (params==1) {
-            prog=true;
+                if (p[0]==HASH_KEYWORD_MAIN) { // <1 MAIN>
-            join=true;
+                        main=true;
-	  }
+            }
-	  else if (p[0]==HASH_KEYWORD_MAIN) { // <1 MAIN>
+#ifndef DISABLE_PROG
-            main=true;
+            else if (p[0] == HASH_KEYWORD_JOIN) {  // <1 JOIN>
-	  }
+                main=true;
-	  else if (p[0]==HASH_KEYWORD_PROG) { // <1 PROG>
+                prog=true;
-            prog=true;
+                join=true;
-	  }
+            }
-	  else break; // will reply <X>
+            else if (p[0]==HASH_KEYWORD_PROG) { // <1 PROG>
-	}
+                prog=true;
-        if (main) TrackManager::setMainPower(POWERMODE::ON);
+            }
-        if (prog) TrackManager::setProgPower(POWERMODE::ON);
+#endif
-        TrackManager::setJoin(join);
+            //else if (p[0] >= 'A' && p[0] <= 'H') { // <1 A-H>
            else if (p[0] >= HASH_KEYWORD_A && p[0] <= HASH_KEYWORD_H) { // <1 A-H>
                byte t = (p[0] - 'A');
                    //DIAG(F("Processing track - %d "), t);
                    if (TrackManager::isProg(t)) {
                        main = false;
                        prog = true;
                    }
                    else
                    {
                        main=true;
                        prog=false;
                    }
                singletrack=true;
                if (main) TrackManager::setTrackPower(false, false, POWERMODE::ON, t);
                if (prog) TrackManager::setTrackPower(true, false, POWERMODE::ON, t);
                StringFormatter::send(stream, F("<1 %c>\n"), t+'A');
                //CommandDistributor::broadcastPower();
                //TrackManager::streamTrackState(NULL,t);
                return;
            }
 	    else break; // will reply <X>
 	    }
        if (!singletrack) {
            TrackManager::setJoin(join);
            if (join) TrackManager::setJoinPower(POWERMODE::ON);
            else {
                if (main) TrackManager::setMainPower(POWERMODE::ON);
                if (prog) TrackManager::setProgPower(POWERMODE::ON);
            }
            CommandDistributor::broadcastPower();
            return;
            }
        CommandDistributor::broadcastPower();
        return;
        }
    case '0': // POWEROFF <0 [MAIN | PROG] >
        {
-        bool main=false;
+            bool main=false;
-        bool prog=false;
+            bool prog=false;
-        if (params > 1) break;
+            bool singletrack=false;
-        if (params==0 || MotorDriver::commonFaultPin) { // <0> or tracks can not be handled individually
+            //byte t=0;
-	  main=true;
+            if (params > 1) break;
-	  prog=true;
+            if (params==0) { // All
-        }
+                main=true;
-	if (params==1) {
+                prog=true;
-	  if (p[0]==HASH_KEYWORD_MAIN) { // <0 MAIN>
+            }
-	    main=true;
+            if (params==1) {
-	  }
+                if (p[0]==HASH_KEYWORD_MAIN) { // <0 MAIN>
-	  else if (p[0]==HASH_KEYWORD_PROG) { // <0 PROG>
+                    main=true;
-	    prog=true;
+            }
-	  }
+#ifndef DISABLE_PROG
-	  else break; // will reply <X>
+            else if (p[0]==HASH_KEYWORD_PROG) { // <0 PROG>
-	}
+                prog=true;
            }
 #endif
            //else if (p[0] >= 'A' && p[0] <= 'H') { // <1 A-H>
             else if (p[0] >= HASH_KEYWORD_A && p[0] <= HASH_KEYWORD_H) { // <1 A-H>
                byte t = (p[0] - 'A');
                //DIAG(F("Processing track - %d "), t);
                if (TrackManager::isProg(t)) {
                    main = false;
                    prog = true;
                }
                else
                {
                    main=true;
                    prog=false;
                }
                singletrack=true;  
                TrackManager::setJoin(false);
                if (main) TrackManager::setTrackPower(false, false, POWERMODE::OFF, t);
                if (prog) {
                    TrackManager::progTrackBoosted=false;  // Prog track boost mode will not outlive prog track off
                    TrackManager::setTrackPower(true, false, POWERMODE::OFF, t);                 
                }   
                StringFormatter::send(stream, F("<0 %c>\n"), t+'A');
                //CommandDistributor::broadcastPower();
                //TrackManager::streamTrackState(NULL, t);
                return;
            }    
-        if (main) TrackManager::setMainPower(POWERMODE::OFF);
+	    else break; // will reply <X>
-        if (prog) {
+	    }
            TrackManager::progTrackBoosted=false;  // Prog track boost mode will not outlive prog track off
            TrackManager::setProgPower(POWERMODE::OFF);
        }
        TrackManager::setJoin(false);
-        CommandDistributor::broadcastPower();
+        if (!singletrack) {
-        return;
+            TrackManager::setJoin(false);
            if (main) TrackManager::setMainPower(POWERMODE::OFF);
            if (prog) {
                    TrackManager::progTrackBoosted=false;  // Prog track boost mode will not outlive prog track off
                    TrackManager::setProgPower(POWERMODE::OFF);
                }
            CommandDistributor::broadcastPower();
            return;
        }
    }
    case '!': // ESTOP ALL  <!>
        DCC::setThrottle(0,1,1); // this broadcasts speed 1(estop) and sets all reminders to speed 1.
@ -547,12 +714,12 @@ void DCCEXParser::parseOne(Print *stream, byte *com, RingStream * ringStream)
    case ' ': // < >
        StringFormatter::send(stream, F("\n"));
        return;
-
+#ifndef DISABLE_DIAG
    case 'D': // < >
        if (parseD(stream, params, p))
            return;
-        return;
+        break;
-
+#endif
    case '=': // <= Track manager control  >
        if (TrackManager::parseJ(stream, params, p))
            return;
@ -637,8 +804,16 @@ void DCCEXParser::parseOne(Print *stream, byte *com, RingStream * ringStream)
                if (params==1) {
                    SENDFLASHLIST(stream,RMFT2::rosterIdList)
                }
-                else StringFormatter::send(stream,F(" %d \"%S\" \"%S\""), 
+                else {
-                    id, RMFT2::getRosterName(id), RMFT2::getRosterFunctions(id));
+                    auto rosterName= RMFT2::getRosterName(id);
                    if (!rosterName) rosterName=F("");
                    auto functionNames= RMFT2::getRosterFunctions(id);
                    if (!functionNames) functionNames=RMFT2::getRosterFunctions(0);
                    if (!functionNames) functionNames=F("");
                    StringFormatter::send(stream,F(" %d \"%S\" \"%S\""), 
 					                            id, rosterName, functionNames);
                }
 #endif          
                StringFormatter::send(stream, F(">\n"));      
                return; 
@ -667,11 +842,73 @@ void DCCEXParser::parseOne(Print *stream, byte *com, RingStream * ringStream)
                }
                StringFormatter::send(stream, F(">\n"));
                return;
 // No turntables without HAL support
 #ifndef IO_NO_HAL
            case HASH_KEYWORD_O: // <JO returns turntable list
                StringFormatter::send(stream, F("<jO"));
                if (params==1) { // <JO>
                    for (Turntable * tto=Turntable::first(); tto; tto=tto->next()) { 
                        if (tto->isHidden()) continue;          
                        StringFormatter::send(stream, F(" %d"),tto->getId());
                    }
                    StringFormatter::send(stream, F(">\n"));
                } else {    // <JO id>
                    Turntable *tto=Turntable::get(id);
                    if (!tto || tto->isHidden()) {
                        StringFormatter::send(stream, F(" %d X>\n"), id);
                    } else {
                        uint8_t pos = tto->getPosition();
                        uint8_t type = tto->isEXTT();
                        uint8_t posCount = tto->getPositionCount();
                        const FSH *todesc = NULL;
 #ifdef EXRAIL_ACTIVE
                        todesc = RMFT2::getTurntableDescription(id);
 #endif
                        if (todesc == NULL) todesc = F("");
                        StringFormatter::send(stream, F(" %d %d %d %d \"%S\">\n"), id, type, pos, posCount, todesc);
                    }
                }
                return;
            case HASH_KEYWORD_P: // <JP id> returns turntable position list for the turntable id
                if (params==2) { // <JP id>
                    Turntable *tto=Turntable::get(id);
                    if (!tto || tto->isHidden()) {
                        StringFormatter::send(stream, F(" %d X>\n"), id);
                    } else {
                        uint8_t posCount = tto->getPositionCount();
                        const FSH *tpdesc = NULL;
                        for (uint8_t p = 0; p < posCount; p++) {
                            StringFormatter::send(stream, F("<jP"));
                            int16_t angle = tto->getPositionAngle(p);
 #ifdef EXRAIL_ACTIVE
                            tpdesc = RMFT2::getTurntablePositionDescription(id, p);
 #endif
                            if (tpdesc == NULL) tpdesc = F("");
                            StringFormatter::send(stream, F(" %d %d %d \"%S\""), id, p, angle, tpdesc);
                            StringFormatter::send(stream, F(">\n"));
                        }
                    }
                } else {
                    StringFormatter::send(stream, F("<jP X>\n"));
                }
                return;
 #endif
            default: break;    
            }  // switch(p[1])
        break; // case J
        }
 // No turntables without HAL support
 #ifndef IO_NO_HAL
    case 'I': // TURNTABLE  <I ...>
        if (parseI(stream, params, p))
            return;
        break;
 #endif
    case 'L': // LCC interface implemented in EXRAIL parser
        break; // Will <X> if not intercepted by EXRAIL 
    default: //anything else will diagnose and drop out to <X>
        DIAG(F("Opcode=%c params=%d"), opcode, params);
        for (int i = 0; i < params; i++)
@ -890,8 +1127,9 @@ bool DCCEXParser::parseD(Print *stream, int16_t params, int16_t p[])
    case HASH_KEYWORD_RAM: // <D RAM>
        StringFormatter::send(stream, F("Free memory=%d\n"), DCCTimer::getMinimumFreeMemory());
-        break;
+        return true;
 #ifndef DISABLE_PROG
    case HASH_KEYWORD_ACK: // <D ACK ON/OFF> <D ACK [LIMIT|MIN|MAX|RETRY] Value>
 	if (params >= 3) {
 	    if (p[1] == HASH_KEYWORD_LIMIT) {
@ -912,6 +1150,7 @@ bool DCCEXParser::parseD(Print *stream, int16_t params, int16_t p[])
 	  Diag::ACK = onOff;
 	}
        return true;
 #endif
    case HASH_KEYWORD_CMD: // <D CMD ON/OFF>
        Diag::CMD = onOff;
@ -934,11 +1173,11 @@ bool DCCEXParser::parseD(Print *stream, int16_t params, int16_t p[])
        Diag::LCN = onOff;
        return true;
 #endif
-
+#ifndef DISABLE_PROG
    case HASH_KEYWORD_PROGBOOST:
        TrackManager::progTrackBoosted=true;
 	    return true;
-
+#endif
    case HASH_KEYWORD_RESET:
        DCCTimer::reset();
        break; // and <X> if we didnt restart 
@ -989,6 +1228,99 @@ bool DCCEXParser::parseD(Print *stream, int16_t params, int16_t p[])
    return false;
 }
 // ==========================
 // Turntable - no support if no HAL
 // <I> - list all
 // <I id> - broadcast type and current position
 // <I id DCC> - create DCC - This is TBA
 // <I id steps> - operate (DCC)
 // <I id steps activity> - operate (EXTT)
 // <I id ADD position value> - add position
 // <I id EXTT i2caddress vpin home> - create EXTT
 #ifndef IO_NO_HAL
 bool DCCEXParser::parseI(Print *stream, int16_t params, int16_t p[])
 {
    switch (params)
    {
    case 0: // <I> list turntable objects
        return Turntable::printAll(stream);
    case 1: // <I id> broadcast type and current position
        {    
            Turntable *tto = Turntable::get(p[0]);
            if (tto) {
                bool type = tto->isEXTT();
                uint8_t position = tto->getPosition();
                StringFormatter::send(stream, F("<I %d %d>\n"), type, position);
            } else {
                return false;
            }
        }
        return true;
    case 2: // <I id position> - rotate a DCC turntable
        {
            Turntable *tto = Turntable::get(p[0]);
            if (tto && !tto->isEXTT()) {
                if (!tto->setPosition(p[0], p[1])) return false;
            } else {
                return false;
            }
        }
        return true;
    case 3: // <I id position activity> | <I id DCC home> - rotate to position for EX-Turntable or create DCC turntable
        {
            Turntable *tto = Turntable::get(p[0]);
            if (p[1] == HASH_KEYWORD_DCC) {
                if (tto || p[2] < 0 || p[2] > 3600) return false;
                if (!DCCTurntable::create(p[0])) return false;
                Turntable *tto = Turntable::get(p[0]);
                tto->addPosition(0, 0, p[2]);
                StringFormatter::send(stream, F("<I>\n"));
            } else {
                if (!tto) return false;
                if (!tto->isEXTT()) return false;
                if (!tto->setPosition(p[0], p[1], p[2])) return false;
            }
        }
        return true;
    case 4: // <I id EXTT vpin home> create an EXTT turntable
        {
            Turntable *tto = Turntable::get(p[0]);
            if (p[1] == HASH_KEYWORD_EXTT) {
                if (tto || p[3] < 0 || p[3] > 3600) return false;
                if (!EXTTTurntable::create(p[0], (VPIN)p[2])) return false;
                Turntable *tto = Turntable::get(p[0]);
                tto->addPosition(0, 0, p[3]);
                StringFormatter::send(stream, F("<I>\n"));
            } else {
                return false;
            }
        }
        return true;
    case 5: // <I id ADD position value angle> add a position
        {
            Turntable *tto = Turntable::get(p[0]);
            if (p[1] == HASH_KEYWORD_ADD) {
                // tto must exist, no more than 48 positions, angle 0 - 3600
                if (!tto || p[2] > 48 || p[4] < 0 || p[4] > 3600) return false;
                tto->addPosition(p[2], p[3], p[4]);
                StringFormatter::send(stream, F("<I>\n"));
            } else {
                return false;
            }
        }
        return true;
    default:    // Anything else is invalid
        return false;
    }
 }
 #endif
 // CALLBACKS must be static
 bool DCCEXParser::stashCallback(Print *stream, int16_t p[MAX_COMMAND_PARAMS], RingStream * ringStream)
 {
--- a/DCCEXParser.h
+++ b/DCCEXParser.h
@ -24,6 +24,7 @@
 #include <Arduino.h>
 #include "FSH.h"
 #include "RingStream.h"
 #include "defines.h"
 typedef void (*FILTER_CALLBACK)(Print * stream, byte & opcode, byte & paramCount, int16_t p[]);
 typedef void (*AT_COMMAND_CALLBACK)(HardwareSerial * stream,const byte * command);
@ -45,13 +46,16 @@ struct DCCEXParser
    static int16_t splitValues( int16_t result[MAX_COMMAND_PARAMS], const byte * command, bool usehex);
    static bool parseT(Print * stream, int16_t params, int16_t p[]);
-     static bool parseZ(Print * stream, int16_t params, int16_t p[]);
+    static bool parseZ(Print * stream, int16_t params, int16_t p[]);
-     static bool parseS(Print * stream,  int16_t params, int16_t p[]);
+    static bool parseS(Print * stream, int16_t params, int16_t p[]);
-     static bool parsef(Print * stream,  int16_t params, int16_t p[]);
+    static bool parsef(Print * stream, int16_t params, int16_t p[]);
-     static bool parseD(Print * stream,  int16_t params, int16_t p[]);
+    static bool parseD(Print * stream, int16_t params, int16_t p[]);
 #ifndef IO_NO_HAL
    static bool parseI(Print * stream, int16_t params, int16_t p[]);
 #endif
-     static Print * getAsyncReplyStream();
+    static Print * getAsyncReplyStream();
-     static void commitAsyncReplyStream();
+    static void commitAsyncReplyStream();
    static bool stashBusy;
    static byte stashTarget;
--- a/DCCRMT.cpp
+++ b/DCCRMT.cpp
@ -194,8 +194,10 @@ int RMTChannel::RMTfillData(const byte buffer[], byte byteCount, byte repeatCoun
  setDCCBit1(data + bitcounter-1);     // overwrite previous zero bit with one bit
  setEOT(data + bitcounter++);         // EOT marker
  dataLen = bitcounter;
  noInterrupts();                      // keep dataReady and dataRepeat consistnet to each other
  dataReady = true;
  dataRepeat = repeatCount+1;         // repeatCount of 0 means send once
  interrupts();
  return 0;
 }
@ -212,6 +214,8 @@ void IRAM_ATTR RMTChannel::RMTinterrupt() {
  if (dataReady) {            // if we have new data, fill while preamble is running
    rmt_fill_tx_items(channel, data, dataLen, preambleLen-1);
    dataReady = false;
    if (dataRepeat == 0)       // all data should go out at least once
      DIAG(F("Channel %d DCC signal lost data"), channel);
  }
  if (dataRepeat > 0)         // if a repeat count was specified, work on that
    dataRepeat--;
--- a/DCCTimer.h
+++ b/DCCTimer.h
@ -1,7 +1,7 @@
 /*
- *  © 2022 Paul M. Antoine
+ *  © 2022-2023 Paul M. Antoine
 *  © 2021 Mike S
- *  © 2021-2022 Harald Barth
+ *  © 2021-2023 Harald Barth
 *  © 2021 Fred Decker
 *  All rights reserved.
 *  
@ -62,6 +62,9 @@ class DCCTimer {
  static bool isPWMPin(byte pin);
  static void setPWM(byte pin, bool high);
  static void clearPWM();
  static void DCCEXanalogWriteFrequency(uint8_t pin, uint32_t frequency);
  static void DCCEXanalogWrite(uint8_t pin, int value);
 // Update low ram level.  Allow for extra bytes to be specified
 // by estimation or inspection, that may be used by other 
 // called subroutines.  Must be called with interrupts disabled.
@ -102,9 +105,14 @@ private:
 // that an offset can be initialized.
 class ADCee {
 public:
-  // init does add the pin to the list of scanned pins (if this
+  // begin is called for any setup that must be done before
  // **init** can be called. On some architectures this involves ADC
  // initialisation and clock routing, sampling times etc.
  static void begin();
  // init adds the pin to the list of scanned pins (if this
  // platform's implementation scans pins) and returns the first
-  // read value. It is called before the regular scan is started.
+  // read value (which is why it required begin to have been called first!)
  // It must be called before the regular scan is started.
  static int init(uint8_t pin);
  // read does read the pin value from the scanned cache or directly
  // if this is a platform that does not scan. fromISR is a hint if
@ -113,19 +121,20 @@ public:
  static int read(uint8_t pin, bool fromISR=false);
  // returns possible max value that the ADC can return
  static int16_t ADCmax();
  // begin is called for any setup that must be done before
  // scan can be called.
  static void begin();
 private:
  // On platforms that scan, it is called from waveform ISR
  // only on a regular basis.
  static void scan();
  #if defined (ARDUINO_ARCH_STM32)
  // bit array of used pins (max 32)
  static uint32_t usedpins;
 #else
  // bit array of used pins (max 16)
  static uint16_t usedpins;
 #endif
  static uint8_t highestPin;
  // cached analog values (malloc:ed to actual number of ADC channels)
  static int *analogvals;
  // ids to scan (new way)
  static byte *idarr;
  // friend so that we can call scan() and begin()
  friend class DCCWaveform;
  };
--- a/DCCTimerAVR.cpp
+++ b/DCCTimerAVR.cpp
@ -1,6 +1,6 @@
 /*
 *  © 2021 Mike S
- *  © 2021-2022 Harald Barth
+ *  © 2021-2023 Harald Barth
 *  © 2021 Fred Decker
 *  © 2021 Chris Harlow
 *  © 2021 David Cutting
@ -29,6 +29,9 @@
 #include <avr/boot.h> 
 #include <avr/wdt.h>
 #include "DCCTimer.h"
 #ifdef DEBUG_ADC
 #include "TrackManager.h"
 #endif
 INTERRUPT_CALLBACK interruptHandler=0;
  // Arduino nano, uno, mega etc
@ -128,8 +131,8 @@ void DCCTimer::reset() {
 #define NUM_ADC_INPUTS 8
 #endif
 uint16_t ADCee::usedpins = 0;
 uint8_t ADCee::highestPin = 0;
 int * ADCee::analogvals = NULL;
 byte *ADCee::idarr = NULL;
 static bool ADCusesHighPort = false;
 /*
@ -139,28 +142,17 @@ static bool ADCusesHighPort = false;
 */
 int ADCee::init(uint8_t pin) {
  uint8_t id = pin - A0;
  byte n;
  if (id >= NUM_ADC_INPUTS)
    return -1023;
  if (id > 7)
    ADCusesHighPort = true;
  pinMode(pin, INPUT);
  int value = analogRead(pin);
-  if (analogvals == NULL) {
+  if (analogvals == NULL)
    analogvals = (int *)calloc(NUM_ADC_INPUTS, sizeof(int));
-    for (n=0 ; n < NUM_ADC_INPUTS; n++) // set unreasonable value at startup as marker
+  analogvals[id] = value;
-      analogvals[n] = -32768;           // 16 bit int min value
+  usedpins |= (1<<id);
-    idarr = (byte *)calloc(NUM_ADC_INPUTS+1, sizeof(byte));  // +1 for terminator value
+  if (id > highestPin) highestPin = id;
    for (n=0 ; n <= NUM_ADC_INPUTS; n++)
      idarr[n] = 255;                   // set 255 as end of array marker
  }
  analogvals[id] = value; // store before enable by idarr[n]
  for (n=0 ; n <= NUM_ADC_INPUTS; n++) {
    if (idarr[n] == 255) {
      idarr[n] = id;
      break;
    }
  }
  return value;
 }
 int16_t ADCee::ADCmax() {
@ -170,14 +162,14 @@ int16_t ADCee::ADCmax() {
 * Read function ADCee::read(pin) to get value instead of analogRead(pin)
 */
 int ADCee::read(uint8_t pin, bool fromISR) {
  (void)fromISR; // AVR does ignore this arg
  uint8_t id = pin - A0;
-  int a;
+  if ((usedpins & (1<<id) ) == 0)
    return -1023;
  // we do not need to check (analogvals == NULL)
  // because usedpins would still be 0 in that case
-  noInterrupts();
+  if (!fromISR) noInterrupts();
-  a = analogvals[id];
+  int a = analogvals[id];
-  interrupts();
+  if (!fromISR) interrupts();
  return a;
 }
 /*
@ -186,7 +178,8 @@ int ADCee::read(uint8_t pin, bool fromISR) {
 #pragma GCC push_options
 #pragma GCC optimize ("-O3")
 void ADCee::scan() {
-  static byte num = 0;       // index into id array
+  static byte id = 0;       // id and mask are the same thing but it is faster to
  static uint16_t mask = 1; // increment and shift instead to calculate mask from id
  static bool waiting = false;
  if (waiting) {
@ -198,26 +191,49 @@ void ADCee::scan() {
    low = ADCL; //must read low before high
    high = ADCH;
    bitSet(ADCSRA, ADIF);
-    analogvals[idarr[num]] = (high << 8) | low;
+    analogvals[id] = (high << 8) | low;
    // advance at least one track
 #ifdef DEBUG_ADC
    if (id == 1) TrackManager::track[1]->setBrake(0);
 #endif
    waiting = false;
    id++;
    mask = mask << 1;
    if (id > highestPin) {
      id = 0;
      mask = 1;
    }
  }
  if (!waiting) {
-    // cycle around in-use analogue pins
+    if (usedpins == 0) // otherwise we would loop forever
-    num++;
+      return;
-    if (idarr[num] == 255)
+    // look for a valid track to sample or until we are around
-      num = 0;
+    while (true) {
-    // start new ADC aquire on id
+      if (mask  & usedpins) {
 	// start new ADC aquire on id
 #if defined(ADCSRB) && defined(MUX5)
-    if (ADCusesHighPort) {     // if we ever have started to use high pins)
+	if (ADCusesHighPort) { // if we ever have started to use high pins)
-      if (idarr[num] > 7)              // if we use a high ADC pin
+	  if (id > 7)          // if we use a high ADC pin
-	bitSet(ADCSRB, MUX5);  // set MUX5 bit
+	    bitSet(ADCSRB, MUX5); // set MUX5 bit
-      else
+	  else
-	bitClear(ADCSRB, MUX5);
+	    bitClear(ADCSRB, MUX5);
-    }
+	}
 #endif
-    ADMUX = (1 << REFS0) | (idarr[num] & 0x07); // select AVCC as reference and set MUX
+	ADMUX=(1<<REFS0)|(id & 0x07); //select AVCC as reference and set MUX
-    bitSet(ADCSRA, ADSC);               // start conversion
+	bitSet(ADCSRA,ADSC); // start conversion
-    waiting = true;
+#ifdef DEBUG_ADC
 	if (id == 1) TrackManager::track[1]->setBrake(1);
 #endif
 	waiting = true;
 	return;
      }
      id++;
      mask = mask << 1;
      if (id > highestPin) {
      	id = 0;
 	      mask = 1;
      }
    }
  }
 }
 #pragma GCC pop_options
--- a/DCCTimerESP.cpp
+++ b/DCCTimerESP.cpp
@ -150,6 +150,45 @@ int DCCTimer::freeMemory() {
 void DCCTimer::reset() {
   ESP.restart();
 }
 #include "esp32-hal.h"
 #include "soc/soc_caps.h"
 #ifdef SOC_LEDC_SUPPORT_HS_MODE
 #define LEDC_CHANNELS           (SOC_LEDC_CHANNEL_NUM<<1)
 #else
 #define LEDC_CHANNELS           (SOC_LEDC_CHANNEL_NUM)
 #endif
 static int8_t pin_to_channel[SOC_GPIO_PIN_COUNT] = { 0 };
 static int cnt_channel = LEDC_CHANNELS;
 void DCCTimer::DCCEXanalogWriteFrequency(uint8_t pin, uint32_t frequency) {
  if (pin < SOC_GPIO_PIN_COUNT) {
    if (pin_to_channel[pin] != 0) {
      ledcSetup(pin_to_channel[pin], frequency, 8);
    }
  }
 }
 void DCCTimer::DCCEXanalogWrite(uint8_t pin, int value) {
  if (pin < SOC_GPIO_PIN_COUNT) {
    if (pin_to_channel[pin] == 0) {
      if (!cnt_channel) {
          log_e("No more PWM channels available! All %u already used", LEDC_CHANNELS);
          return;
      }
      pin_to_channel[pin] = --cnt_channel;
      ledcSetup(cnt_channel, 1000, 8);
      ledcAttachPin(pin, cnt_channel);
    } else {
      ledcAttachPin(pin, pin_to_channel[pin]);
    }
    ledcWrite(pin_to_channel[pin], value);
  }
 }
 int ADCee::init(uint8_t pin) {
  pinMode(pin, ANALOG);
  adc1_config_width(ADC_WIDTH_BIT_12);
--- a/DCCTimerSAMD.cpp
+++ b/DCCTimerSAMD.cpp
@ -162,7 +162,7 @@ uint16_t ADCee::usedpins = 0;
 int * ADCee::analogvals = NULL;
 int ADCee::init(uint8_t pin) {
-  uint id = pin - A0;
+  uint8_t id = pin - A0;
  int value = 0;
  if (id > NUM_ADC_INPUTS)
@ -210,7 +210,7 @@ int ADCee::read(uint8_t pin, bool fromISR) {
 #pragma GCC push_options
 #pragma GCC optimize ("-O3")
 void ADCee::scan() {
-  static uint id = 0;        // id and mask are the same thing but it is faster to 
+  static uint8_t id = 0;        // id and mask are the same thing but it is faster to 
  static uint16_t mask = 1;  // increment and shift instead to calculate mask from id
  static bool waiting = false;
--- a/DCCTimerSTM32.cpp
+++ b/DCCTimerSTM32.cpp
@ -1,8 +1,8 @@
 /*
 *  © 2023 Neil McKechnie
- *  © 2022 Paul M. Antoine
+ *  © 2022-2023 Paul M. Antoine
 *  © 2021 Mike S
- *  © 2021 Harald Barth
+ *  © 2021, 2023 Harald Barth
 *  © 2021 Fred Decker
 *  © 2021 Chris Harlow
 *  © 2021 David Cutting
@ -30,24 +30,35 @@
 #ifdef ARDUINO_ARCH_STM32
 #include "DCCTimer.h"
 #ifdef DEBUG_ADC
 #include "TrackManager.h"
 #endif
 #include "DIAG.h"
-#if defined(ARDUINO_NUCLEO_F411RE)
+#if defined(ARDUINO_NUCLEO_F401RE) || defined(ARDUINO_NUCLEO_F411RE)
-// Nucleo-64 boards don't have Serial1 defined by default
+// Nucleo-64 boards don't have additional serial ports defined by default
 HardwareSerial Serial1(PB7, PA15);  // Rx=PB7, Tx=PA15 -- CN7 pins 17 and 21 - F411RE
 // Serial2 is defined to use USART2 by default, but is in fact used as the diag console
 // via the debugger on the Nucleo-64. It is therefore unavailable for other DCC-EX uses like WiFi, DFPlayer, etc.
 // Let's define Serial6 as an additional serial port (the only other option for the Nucleo-64s)
 HardwareSerial Serial6(PA12, PA11);  // Rx=PA12, Tx=PA11 -- CN10 pins 12 and 14 - F411RE
 #elif defined(ARDUINO_NUCLEO_F446RE)
-// Nucleo-64 boards don't have Serial1 defined by default
+// Nucleo-64 boards don't have additional serial ports defined by default
-HardwareSerial Serial1(PA10, PB6);  // Rx=PA10 (D2), Tx=PB6 (D10) -- CN10 pins 17 and 9 - F446RE 
+// On the F446RE, Serial1 isn't really useable as it's Rx/Tx pair sit on already used D2/D10 pins
 // HardwareSerial Serial1(PA10, PB6);  // Rx=PA10 (D2), Tx=PB6 (D10) -- CN10 pins 17 and 9 - F446RE 
 // Serial2 is defined to use USART2 by default, but is in fact used as the diag console
 // via the debugger on the Nucleo-64. It is therefore unavailable for other DCC-EX uses like WiFi, DFPlayer, etc.
-#elif defined(ARDUINO_NUCLEO_F412ZG) || defined(ARDUINO_NUCLEO_F429ZI) || defined(ARDUINO_NUCLEO_F446ZE)
+// On the F446RE, Serial3 and Serial5 are easy to use:
 HardwareSerial Serial3(PC11, PC10);  // Rx=PC11, Tx=PC10 -- USART3 - F446RE
 HardwareSerial Serial5(PD2, PC12);  // Rx=PC7, Tx=PC6 -- UART5 - F446RE
 // On the F446RE, Serial4 and Serial6 also use pins we can't readily map while using the Arduino pins
 #elif defined(ARDUINO_NUCLEO_F412ZG) || defined(ARDUINO_NUCLEO_F413ZH) || defined(ARDUINO_NUCLEO_F429ZI) || defined(ARDUINO_NUCLEO_F446ZE) 
 // Nucleo-144 boards don't have Serial1 defined by default
-HardwareSerial Serial1(PG9, PG14);  // Rx=PG9, Tx=PG14 -- D0, D1 - F412ZG/F446ZE
+HardwareSerial Serial6(PG9, PG14);  // Rx=PG9, Tx=PG14 -- USART6
 // Serial3 is defined to use USART3 by default, but is in fact used as the diag console
 // via the debugger on the Nucleo-144. It is therefore unavailable for other DCC-EX uses like WiFi, DFPlayer, etc.
 #else
-#warning Serial1 not defined
+#error STM32 board selected is not yet explicitly supported - so Serial1 peripheral is not defined
 #endif
 ///////////////////////////////////////////////////////////////////////////////////////////////
@ -143,13 +154,28 @@ HardwareSerial Serial1(PG9, PG14);  // Rx=PG9, Tx=PG14 -- D0, D1 - F412ZG/F446ZE
 ///////////////////////////////////////////////////////////////////////////////////////////////
 INTERRUPT_CALLBACK interruptHandler=0;
-// Let's use STM32's timer #11 until disabused of this notion
+
-// Timer #11 is used for "servo" library, but as DCC-EX is not using
+// On STM32F4xx models that have them, Timers 6 and 7 have no PWM output capability,
-// this libary, we should be free and clear.
+// so are good choices for general timer duties - they are used for tone and servo
-HardwareTimer timer(TIM11);
+// in stm32duino so we shall usurp those as DCC-EX doesn't use tone or servo libs.
 // NB: the F401, F410 and F411 do **not** have Timer 6 or 7, so we use Timer 11
 #ifndef DCC_EX_TIMER
 #if defined(TIM6)
 #define DCC_EX_TIMER TIM6
 #elif defined(TIM7)
 #define DCC_EX_TIMER TIM7
 #elif defined(TIM11)
 #define DCC_EX_TIMER TIM11
 #else
 #warning This STM32F4XX variant does not have Timers 6,7 or 11!!
 #endif
 #endif // ifndef DCC_EX_TIMER
 HardwareTimer dcctimer(DCC_EX_TIMER);
 void DCCTimer_Handler() __attribute__((interrupt));
 // Timer IRQ handler
-void Timer11_Handler() {
+void DCCTimer_Handler() {
  interruptHandler();
 }
@ -157,22 +183,24 @@ void DCCTimer::begin(INTERRUPT_CALLBACK callback) {
  interruptHandler=callback;
  noInterrupts();
-  // adc_set_sample_rate(ADC_SAMPLETIME_480CYCLES);
+  dcctimer.pause();
-  timer.pause();
+  dcctimer.setPrescaleFactor(1);
  timer.setPrescaleFactor(1);
 //  timer.setOverflow(CLOCK_CYCLES * 2);
-  timer.setOverflow(DCC_SIGNAL_TIME, MICROSEC_FORMAT);
+  dcctimer.setOverflow(DCC_SIGNAL_TIME, MICROSEC_FORMAT);
-  timer.attachInterrupt(Timer11_Handler);
+  // dcctimer.attachInterrupt(Timer11_Handler);
-  timer.refresh();
+  dcctimer.attachInterrupt(DCCTimer_Handler);
-  timer.resume();
+  dcctimer.setInterruptPriority(0, 0); // Set highest preemptive priority!
  dcctimer.refresh();
  dcctimer.resume();
  interrupts();
 }
 bool DCCTimer::isPWMPin(byte pin) {
-  //TODO: SAMD whilst this call to digitalPinHasPWM will reveal which pins can do PWM,
+  //TODO: STM32 whilst this call to digitalPinHasPWM will reveal which pins can do PWM,
  //      there's no support yet for High Accuracy, so for now return false
  //  return digitalPinHasPWM(pin);
  (void) pin;
  return false;
 }
@ -224,28 +252,128 @@ void DCCTimer::reset() {
    while(true) {};
 }
 // TODO: rationalise the size of these... could really use sparse arrays etc.
 static HardwareTimer * pin_timer[100] = {0};
 static uint32_t channel_frequency[100] = {0};
 static uint32_t pin_channel[100] = {0};
 // Using the HardwareTimer library API included in stm32duino core to handle PWM duties
 // TODO: in order to use the HA code above which Neil kindly wrote, we may have to do something more
 // sophisticated about detecting any clash between the timer we'd like to use for PWM and the ones
 // currently used for HA so they don't interfere with one another. For now we'll just make PWM
 // work well... then work backwards to integrate with HA mode if we can.
 void DCCTimer::DCCEXanalogWriteFrequency(uint8_t pin, uint32_t frequency)
 {
  if (pin_timer[pin] == NULL) {
    // Automatically retrieve TIM instance and channel associated to pin
    // This is used to be compatible with all STM32 series automatically.
    TIM_TypeDef *Instance = (TIM_TypeDef *)pinmap_peripheral(digitalPinToPinName(pin), PinMap_PWM);
    if (Instance == NULL) {
      // We shouldn't get here (famous last words) as it ought to have been caught by brakeCanPWM()!
      DIAG(F("DCCEXanalogWriteFrequency::Pin %d has no PWM function!"), pin);
      return;
    }
    pin_channel[pin] = STM_PIN_CHANNEL(pinmap_function(digitalPinToPinName(pin), PinMap_PWM));
    // Instantiate HardwareTimer object. Thanks to 'new' instantiation,
    // HardwareTimer is not destructed when setup function is finished.
    pin_timer[pin] = new HardwareTimer(Instance);
    // Configure and start PWM
    // MyTim->setPWM(channel, pin, 5, 10, NULL, NULL); // No callback required, we can simplify the function call
    if (pin_timer[pin] != NULL)
    {
      pin_timer[pin]->setPWM(pin_channel[pin], pin, frequency, 0); // set frequency in Hertz, 0% dutycycle
      DIAG(F("DCCEXanalogWriteFrequency::Pin %d on Timer %d, frequency %d"), pin, pin_channel[pin], frequency);
    }
    else
      DIAG(F("DCCEXanalogWriteFrequency::failed to allocate HardwareTimer instance!"));
  }
  else
  {
    // Frequency change request
    if (frequency != channel_frequency[pin])
    {
      pinmap_pinout(digitalPinToPinName(pin), PinMap_TIM); // ensure the pin has been configured!
      pin_timer[pin]->setOverflow(frequency, HERTZ_FORMAT); // Just change the frequency if it's already running!
      DIAG(F("DCCEXanalogWriteFrequency::setting frequency to %d"), frequency);
    }
  }
  channel_frequency[pin] = frequency;
  return;
 }
 void DCCTimer::DCCEXanalogWrite(uint8_t pin, int value) {
    // Calculate percentage duty cycle from value given
    uint32_t duty_cycle = (value * 100 / 256) + 1;
    if (pin_timer[pin] != NULL) {
      // if (duty_cycle == 100)
      // {
      //   pin_timer[pin]->pauseChannel(pin_channel[pin]);
      //   DIAG(F("DCCEXanalogWrite::Pausing timer channel on pin %d"), pin);
      // }
      // else
      // {
        pinmap_pinout(digitalPinToPinName(pin), PinMap_TIM); // ensure the pin has been configured!
        // pin_timer[pin]->resumeChannel(pin_channel[pin]);
        pin_timer[pin]->setCaptureCompare(pin_channel[pin], duty_cycle, PERCENT_COMPARE_FORMAT); // DCC_EX_PWM_FREQ Hertz, duty_cycle% dutycycle
        DIAG(F("DCCEXanalogWrite::Pin %d, value %d, duty cycle %d"), pin, value, duty_cycle);
      // }
    }
    else
      DIAG(F("DCCEXanalogWrite::Pin %d is not configured for PWM!"), pin);
 }
 // Now we can handle more ADCs, maybe this works!
 #define NUM_ADC_INPUTS NUM_ANALOG_INPUTS
-// TODO: may need to use uint32_t on STMF4xx variants with > 16 analog inputs!
+uint32_t ADCee::usedpins = 0;         // Max of 32 ADC input channels!
-uint16_t ADCee::usedpins = 0;
+uint8_t ADCee::highestPin = 0;        // Highest pin to scan
-int * ADCee::analogvals = NULL;
+int * ADCee::analogvals = NULL;       // Array of analog values last captured
-uint32_t * analogchans = NULL;
+uint32_t * analogchans = NULL;        // Array of channel numbers to be scanned
-bool adc1configured = false;
+// bool adc1configured = false;
 ADC_TypeDef * * adcchans = NULL;      // Array to capture which ADC is each input channel on
-int16_t ADCee::ADCmax() {
+int16_t ADCee::ADCmax()
-  return 4095;
+{
    return 4095;
 }
 int ADCee::init(uint8_t pin) {
  uint id = pin - A0;
  int value = 0;
  PinName stmpin = digitalPin[analogInputPin[id]];
  uint32_t stmgpio = stmpin / 16; // 16-bits per GPIO port group on STM32
  uint32_t adcchan =  STM_PIN_CHANNEL(pinmap_function(stmpin, PinMap_ADC)); // find ADC channel (only valid for ADC1!)
  GPIO_TypeDef * gpioBase;
-  // Port config - find which port we're on and power it up
+  int value = 0;
-  switch(stmgpio) {
+  PinName stmpin = analogInputToPinName(pin);
  if (stmpin == NC) // do not continue if this is not an analog pin at all
    return -1024;   // some silly value as error
  uint32_t stmgpio = STM_PORT(stmpin); // converts to the GPIO port (16-bits per port group on STM32)
  uint32_t adcchan =  STM_PIN_CHANNEL(pinmap_function(stmpin, PinMap_ADC)); // find ADC input channel
  ADC_TypeDef *adc = (ADC_TypeDef *)pinmap_find_peripheral(stmpin, PinMap_ADC); // find which ADC this pin is on ADC1/2/3 etc.
  int adcnum = 1;
  if (adc == ADC1)
    DIAG(F("ADCee::init(): found pin %d on ADC1"), pin);
 // Checking for ADC2 and ADC3 being defined helps cater for more variants later
 #if defined(ADC2)
  else if (adc == ADC2)
  {
    DIAG(F("ADCee::init(): found pin %d on ADC2"), pin);
    adcnum = 2;
  }
 #endif
 #if defined(ADC3)
  else if (adc == ADC3)
  {
    DIAG(F("ADCee::init(): found pin %d on ADC3"), pin);
    adcnum = 3;
  }
 #endif
  else DIAG(F("ADCee::init(): found pin %d on unknown ADC!"), pin);
    // Port config - find which port we're on and power it up
    GPIO_TypeDef *gpioBase;
    switch (stmgpio)
    {
    case 0x00:
        RCC->AHB1ENR |= RCC_AHB1ENR_GPIOAEN; //Power up PORTA
        gpioBase = GPIOA;
@ -258,31 +386,62 @@ int ADCee::init(uint8_t pin) {
        RCC->AHB1ENR |= RCC_AHB1ENR_GPIOCEN; //Power up PORTC
        gpioBase = GPIOC;
        break;
    case 0x03:
        RCC->AHB1ENR |= RCC_AHB1ENR_GPIODEN; //Power up PORTD
        gpioBase = GPIOD;
        break;
    case 0x04:
        RCC->AHB1ENR |= RCC_AHB1ENR_GPIOEEN; //Power up PORTE
        gpioBase = GPIOE;
        break;
 #if defined(GPIOF)
    case 0x05:
        RCC->AHB1ENR |= RCC_AHB1ENR_GPIOFEN; //Power up PORTF
        gpioBase = GPIOF;
        break;
 #endif
    default:
      return -1023; // some silly value as error
  }
-  // Set pin mux mode to analog input
+  // Set pin mux mode to analog input, the 32 bit port mode register has 2 bits per pin
-  gpioBase->MODER |= (0b011 << (stmpin << 1)); // Set pin mux to analog mode
+  gpioBase->MODER |= (0b011 << (STM_PIN(stmpin) << 1)); // Set pin mux to analog mode (binary 11)
  // Set the sampling rate for that analog input
  // This is F411x specific! Different on for example F334
  // STM32F11xC/E Reference manual
  // 11.12.4 ADC sample time register 1 (ADC_SMPR1) (channels 10 to 18)
  // 11.12.5 ADC sample time register 2 (ADC_SMPR2) (channels 0 to 9)
  if (adcchan > 18)
    return -1022; // silly value as error
  if (adcchan < 10)
-    ADC1->SMPR2 |= (0b111 << (adcchan * 3)); // Channel sampling rate 480 cycles
+    adc->SMPR2 |= (0b111 << (adcchan * 3)); // Channel sampling rate 480 cycles
  else
-    ADC1->SMPR1 |= (0b111 << ((adcchan - 10) * 3)); // Channel sampling rate 480 cycles
+    adc->SMPR1 |= (0b111 << ((adcchan - 10) * 3)); // Channel sampling rate 480 cycles
  // Read the inital ADC value for this analog input
-  ADC1->SQR3 = adcchan;           // 1st conversion in regular sequence
+  adc->SQR3 = adcchan;           // 1st conversion in regular sequence
-  ADC1->CR2 |= (1 << 30);         // Start 1st conversion SWSTART
+  adc->CR2 |= ADC_CR2_SWSTART;   //(1 << 30);                     // Start 1st conversion SWSTART
-  while(!(ADC1->SR & (1 << 1)));  // Wait until conversion is complete
+  while(!(adc->SR & (1 << 1)));  // Wait until conversion is complete
-  value = ADC1->DR;               // Read value from register
+  value = adc->DR;               // Read value from register
-  if (analogvals == NULL)
+  uint8_t id = pin - PNUM_ANALOG_BASE;
-  {
+  // if (id > 15) { // today we have not enough bits in the mask to support more
  //   return -1021;
  // }
  if (analogvals == NULL) {  // allocate analogvals, analogchans and adcchans if this is the first invocation of init
    analogvals = (int *)calloc(NUM_ADC_INPUTS+1, sizeof(int));
    analogchans = (uint32_t *)calloc(NUM_ADC_INPUTS+1, sizeof(uint32_t));
    adcchans = (ADC_TypeDef **)calloc(NUM_ADC_INPUTS+1, sizeof(ADC_TypeDef));
  }
  analogvals[id] = value;     // Store sampled value
  analogchans[id] = adcchan;  // Keep track of which ADC channel is used for reading this pin
-  usedpins |= (1 << id);      // This pin is now ready
+  adcchans[id] = adc;         // Keep track of which ADC this channel is on
  usedpins |= (1 << id);                // This pin is now ready
  if (id > highestPin) highestPin = id; // Store our highest pin in use
  DIAG(F("ADCee::init(): value=%d, ADC%d: channel=%d, id=%d"), value, adcnum, adcchan, id);
  return value;
 }
@ -291,7 +450,7 @@ int ADCee::init(uint8_t pin) {
 * Read function ADCee::read(pin) to get value instead of analogRead(pin)
 */
 int ADCee::read(uint8_t pin, bool fromISR) {
-  uint8_t id = pin - A0;
+  uint8_t id = pin - PNUM_ANALOG_BASE;
  // Was this pin initialised yet?
  if ((usedpins & (1<<id) ) == 0)
    return -1023;
@ -306,22 +465,27 @@ int ADCee::read(uint8_t pin, bool fromISR) {
 #pragma GCC push_options
 #pragma GCC optimize ("-O3")
 void ADCee::scan() {
-  static uint id = 0;        // id and mask are the same thing but it is faster to 
+  static uint8_t id = 0;     // id and mask are the same thing but it is faster to
  static uint16_t mask = 1;  // increment and shift instead to calculate mask from id
  static bool waiting = false;
  static ADC_TypeDef *adc;
-  if (waiting) {
+  adc = adcchans[id];
  if (waiting)
  {
    // look if we have a result
-    if (!(ADC1->SR & (1 << 1)))
+    if (!(adc->SR & (1 << 1)))
      return; // no result, continue to wait
    // found value
-    analogvals[id] = ADC1->DR;
+    analogvals[id] = adc->DR;
    // advance at least one track
-    // for scope debug TrackManager::track[1]->setBrake(0);
+#ifdef DEBUG_ADC
    if (id == 1) TrackManager::track[1]->setBrake(0);
 #endif
    waiting = false;
    id++;
    mask = mask << 1;
-    if (id == NUM_ADC_INPUTS+1) {
+    if (id > highestPin) { // the 1 has been shifted out
      id = 0;
      mask = 1;
    }
@ -332,18 +496,21 @@ void ADCee::scan() {
    // look for a valid track to sample or until we are around
    while (true) {
      if (mask  & usedpins) {
-    	  // start new ADC aquire on id
+        // start new ADC aquire on id
-        ADC1->SQR3 = analogchans[id]; //1st conversion in regular sequence
+        adc = adcchans[id];
-        ADC1->CR2 |= (1 << 30); //Start 1st conversion SWSTART
+        adc->SQR3 = analogchans[id]; // 1st conversion in regular sequence
-	      // for scope debug TrackManager::track[1]->setBrake(1);
+        adc->CR2 |= (1 << 30);       // Start 1st conversion SWSTART
-	      waiting = true;
+#ifdef DEBUG_ADC
-	      return;
+	if (id == 1) TrackManager::track[1]->setBrake(1);
 #endif
 	waiting = true;
 	return;
      }
      id++;
      mask = mask << 1;
-      if (id == NUM_ADC_INPUTS+1) {
+      if (id > highestPin) {
-	      id = 0;
+      	id = 0;
-	      mask = 1;
+      	mask = 1;
      }
    }
  }
@ -353,19 +520,83 @@ void ADCee::scan() {
 void ADCee::begin() {
  noInterrupts();
  //ADC1 config sequence
-  // TODO: currently defaults to ADC1, may need more to handle other members of STM32F4xx family
+  RCC->APB2ENR |= RCC_APB2ENR_ADC1EN; // Enable ADC1 clock
  RCC->APB2ENR |= (1 << 8); //Enable ADC1 clock (Bit8) 
  // Set ADC prescaler - DIV8 ~ 40ms, DIV6 ~ 30ms, DIV4 ~ 20ms, DIV2 ~ 11ms
  ADC->CCR = (0 << 16); // Set prescaler 0=DIV2, 1=DIV4, 2=DIV6, 3=DIV8
  ADC1->CR1 &= ~(1 << 8); //SCAN mode disabled (Bit8)
  ADC1->CR1 &= ~(3 << 24); //12bit resolution (Bit24,25 0b00)
  ADC1->SQR1 = (1 << 20); //Set number of conversions projected (L[3:0] 0b0001) -> 1 conversion
  // Disable the DMA controller for ADC1
  ADC1->CR2 &= ~ADC_CR2_DMA;
  ADC1->CR2 &= ~(1 << 1); //Single conversion
  ADC1->CR2 &= ~(1 << 11); //Right alignment of data bits bit12....bit0
  ADC1->SQR1 &= ~(0x3FFFFFFF); //Clear whole 1st 30bits in register
  ADC1->SQR2 &= ~(0x3FFFFFFF); //Clear whole 1st 30bits in register
  ADC1->SQR3 &= ~(0x3FFFFFFF); //Clear whole 1st 30bits in register
  ADC1->CR2 |= (1 << 0); // Switch on ADC1
  // Wait for ADC1 to become ready (calibration complete)
  while (!(ADC1->CR2 & ADC_CR2_ADON)) {
  }
 #if defined(ADC2)
  // Enable the ADC2 clock
  RCC->APB2ENR |= RCC_APB2ENR_ADC2EN;
  // Initialize ADC2
  ADC2->CR1 = 0; // Disable all channels
  ADC2->CR2 = 0; // Clear CR2 register
  ADC2->CR1 &= ~(1 << 8); //SCAN mode disabled (Bit8)
  ADC2->CR1 &= ~(3 << 24); //12bit resolution (Bit24,25 0b00)
  ADC2->SQR1 = (1 << 20); //Set number of conversions projected (L[3:0] 0b0001) -> 1 conversion
  ADC2->CR2 &= ~ADC_CR2_DMA;   // Disable the DMA controller for ADC3
  ADC2->CR2 &= ~(1 << 1); //Single conversion
  ADC2->CR2 &= ~(1 << 11); //Right alignment of data bits bit12....bit0
  ADC2->SQR1 &= ~(0x3FFFFFFF); //Clear whole 1st 30bits in register
  ADC2->SQR2 &= ~(0x3FFFFFFF); //Clear whole 1st 30bits in register
  ADC2->SQR3 &= ~(0x3FFFFFFF); //Clear whole 1st 30bits in register
  // Enable the ADC
  ADC2->CR2 |= ADC_CR2_ADON;
  // Wait for ADC2 to become ready (calibration complete)
  while (!(ADC2->CR2 & ADC_CR2_ADON)) {
  }
  // Perform ADC3 calibration (optional)
  // ADC3->CR2 |= ADC_CR2_CAL;
  // while (ADC3->CR2 & ADC_CR2_CAL) {
  // }
 #endif
 #if defined(ADC3)
  // Enable the ADC3 clock
  RCC->APB2ENR |= RCC_APB2ENR_ADC3EN;
  // Initialize ADC3
  ADC3->CR1 = 0; // Disable all channels
  ADC3->CR2 = 0; // Clear CR2 register
  ADC3->CR1 &= ~(1 << 8); //SCAN mode disabled (Bit8)
  ADC3->CR1 &= ~(3 << 24); //12bit resolution (Bit24,25 0b00)
  ADC3->SQR1 = (1 << 20); //Set number of conversions projected (L[3:0] 0b0001) -> 1 conversion
  ADC3->CR2 &= ~ADC_CR2_DMA;   // Disable the DMA controller for ADC3
  ADC3->CR2 &= ~(1 << 1); //Single conversion
  ADC3->CR2 &= ~(1 << 11); //Right alignment of data bits bit12....bit0
  ADC3->SQR1 &= ~(0x3FFFFFFF); //Clear whole 1st 30bits in register
  ADC3->SQR2 &= ~(0x3FFFFFFF); //Clear whole 1st 30bits in register
  ADC3->SQR3 &= ~(0x3FFFFFFF); //Clear whole 1st 30bits in register
  // Enable the ADC
  ADC3->CR2 |= ADC_CR2_ADON;
  // Wait for ADC3 to become ready (calibration complete)
  while (!(ADC3->CR2 & ADC_CR2_ADON)) {
  }
  // Perform ADC3 calibration (optional)
  // ADC3->CR2 |= ADC_CR2_CAL;
  // while (ADC3->CR2 & ADC_CR2_CAL) {
  // }
 #endif
  interrupts();
 }
 #endif
--- a/DCCWaveform.cpp
+++ b/DCCWaveform.cpp
@ -247,6 +247,9 @@ void DCCWaveform::schedulePacket(const byte buffer[], byte byteCount, byte repea
  pendingPacket[byteCount] = checksum;
  pendingLength = byteCount + 1;
  pendingRepeats = repeats;
 // DIAG repeated commands (accesories)
 //  if (pendingRepeats > 0)
 //    DIAG(F("Repeats=%d on %s track"), pendingRepeats, isMainTrack ? "MAIN" : "PROG");
  // The resets will be zero not only now but as well repeats packets into the future
  clearResets(repeats+1);
  {
--- a/ESP32-fixes.cpp
+++ b/ESP32-fixes.cpp
@ -1,61 +0,0 @@
 /*
 *  © 2022 Harald Barth
 *  All rights reserved.
 *  
 *  This file is part of CommandStation-EX
 *
 *  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/>.
 */
 #ifdef ARDUINO_ARCH_ESP32
 #include <Arduino.h>
 #include "ESP32-fixes.h"
 #include "esp32-hal.h"
 #include "soc/soc_caps.h"
 #ifdef SOC_LEDC_SUPPORT_HS_MODE
 #define LEDC_CHANNELS           (SOC_LEDC_CHANNEL_NUM<<1)
 #else
 #define LEDC_CHANNELS           (SOC_LEDC_CHANNEL_NUM)
 #endif
 static int8_t pin_to_channel[SOC_GPIO_PIN_COUNT] = { 0 };
 static int cnt_channel = LEDC_CHANNELS;
 void DCCEXanalogWriteFrequency(uint8_t pin, uint32_t frequency) {
  if (pin < SOC_GPIO_PIN_COUNT) {
    if (pin_to_channel[pin] != 0) {
      ledcSetup(pin_to_channel[pin], frequency, 8);
    }
  }
 }
 void DCCEXanalogWrite(uint8_t pin, int value) {
  if (pin < SOC_GPIO_PIN_COUNT) {
    if (pin_to_channel[pin] == 0) {
      if (!cnt_channel) {
          log_e("No more PWM channels available! All %u already used", LEDC_CHANNELS);
          return;
      }
      pin_to_channel[pin] = --cnt_channel;
      ledcAttachPin(pin, cnt_channel);
      ledcSetup(cnt_channel, 1000, 8);
    } else {
      ledcAttachPin(pin, pin_to_channel[pin]);
    }
    ledcWrite(pin_to_channel[pin], value);
  }
 }
 #endif
--- a/ESP32-fixes.h
+++ b/ESP32-fixes.h
@ -1,26 +0,0 @@
 /*
 *  © 2022 Harald Barth
 *  All rights reserved.
 *  
 *  This file is part of CommandStation-EX
 *
 *  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/>.
 */
 #ifdef ARDUINO_ARCH_ESP32
 #pragma once
 #include <Arduino.h>
 void DCCEXanalogWriteFrequency(uint8_t pin, uint32_t frequency);
 void DCCEXanalogWrite(uint8_t pin, int value);
 #endif
--- a/EX-CommandStation-installer.exe
+++ b/EX-CommandStation-installer.exe
--- a/EXRAIL2.cpp
+++ b/EXRAIL2.cpp
@ -2,6 +2,7 @@
 *  © 2021 Neil McKechnie
 *  © 2021-2023 Harald Barth
 *  © 2020-2023 Chris Harlow
 *  © 2022-2023 Colin Murdoch
 *  All rights reserved.
 *  
 *  This file is part of CommandStation-EX
@ -51,6 +52,8 @@
 #include "Turnouts.h"
 #include "CommandDistributor.h"
 #include "TrackManager.h"
 #include "Turntables.h"
 #include "IODevice.h"
 // Command parsing keywords
 const int16_t HASH_KEYWORD_EXRAIL=15435;    
@ -82,7 +85,7 @@ RMFT2 * RMFT2::pausingTask=NULL; // Task causing a PAUSE.
 // when pausingTask is set, that is the ONLY task that gets any service,
 // and all others will have their locos stopped, then resumed after the pausing task resumes.
 byte RMFT2::flags[MAX_FLAGS];
-
+Print * RMFT2::LCCSerial=0;
 LookList *  RMFT2::sequenceLookup=NULL;
 LookList *  RMFT2::onThrowLookup=NULL;
 LookList *  RMFT2::onCloseLookup=NULL;
@ -93,6 +96,10 @@ LookList *  RMFT2::onAmberLookup=NULL;
 LookList *  RMFT2::onGreenLookup=NULL;
 LookList *  RMFT2::onChangeLookup=NULL;
 LookList *  RMFT2::onClockLookup=NULL;
 #ifndef IO_NO_HAL
 LookList *  RMFT2::onRotateLookup=NULL;
 #endif
 LookList *  RMFT2::onOverloadLookup=NULL;
 #define GET_OPCODE GETHIGHFLASH(RMFT2::RouteCode,progCounter)
 #define SKIPOP progCounter+=3
@ -169,20 +176,26 @@ LookList* RMFT2::LookListLoader(OPCODE op1, OPCODE op2, OPCODE op3) {
  onCloseLookup=LookListLoader(OPCODE_ONCLOSE);
  onActivateLookup=LookListLoader(OPCODE_ONACTIVATE);
  onDeactivateLookup=LookListLoader(OPCODE_ONDEACTIVATE);
  onRedLookup=LookListLoader(OPCODE_ONRED);
  onAmberLookup=LookListLoader(OPCODE_ONAMBER);
  onGreenLookup=LookListLoader(OPCODE_ONGREEN);
  onChangeLookup=LookListLoader(OPCODE_ONCHANGE);
  onClockLookup=LookListLoader(OPCODE_ONTIME);
-
+#ifndef IO_NO_HAL
  onRotateLookup=LookListLoader(OPCODE_ONROTATE);
 #endif
  onOverloadLookup=LookListLoader(OPCODE_ONOVERLOAD);
  // onLCCLookup is not the same so not loaded here. 
  // Second pass startup, define any turnouts or servos, set signals red
  // add sequences onRoutines to the lookups
 if (compileFeatures & FEATURE_SIGNAL) {
  onRedLookup=LookListLoader(OPCODE_ONRED);
  onAmberLookup=LookListLoader(OPCODE_ONAMBER);
  onGreenLookup=LookListLoader(OPCODE_ONGREEN);
  for (int sigslot=0;;sigslot++) {
    VPIN sigid=GETHIGHFLASHW(RMFT2::SignalDefinitions,sigslot*8);
    if (sigid==0) break;  // end of signal list
    doSignal(sigid & SIGNAL_ID_MASK, SIGNAL_RED);
  }
  }
  int progCounter;
  for (progCounter=0;; SKIPOP){
@ -194,6 +207,7 @@ LookList* RMFT2::LookListLoader(OPCODE op1, OPCODE op2, OPCODE op3) {
    case OPCODE_AT:
    case OPCODE_ATTIMEOUT2:
    case OPCODE_AFTER:
    case OPCODE_AFTEROVERLOAD:
    case OPCODE_IF:
    case OPCODE_IFNOT: {
      int16_t pin = (int16_t)operand;
@ -238,6 +252,37 @@ LookList* RMFT2::LookListLoader(OPCODE op1, OPCODE op2, OPCODE op3) {
      break;
    }
 #ifndef IO_NO_HAL
    case OPCODE_DCCTURNTABLE: {
      VPIN id=operand;
      int home=getOperand(progCounter,1);
      setTurntableHiddenState(DCCTurntable::create(id));
      Turntable *tto=Turntable::get(id);
      tto->addPosition(0,0,home);
      break;
    }
    case OPCODE_EXTTTURNTABLE: {
      VPIN id=operand;
      VPIN pin=getOperand(progCounter,1);
      int home=getOperand(progCounter,3);
      setTurntableHiddenState(EXTTTurntable::create(id,pin));
      Turntable *tto=Turntable::get(id);
      tto->addPosition(0,0,home);
      break;
    }
    case OPCODE_TTADDPOSITION: {
      VPIN id=operand;
      int position=getOperand(progCounter,1);
      int value=getOperand(progCounter,2);
      int angle=getOperand(progCounter,3);
      Turntable *tto=Turntable::get(id);
      tto->addPosition(position,value,angle);
      break;
    }
 #endif
    case OPCODE_AUTOSTART:
      // automatically create a task from here at startup.
      // Removed if (progCounter>0) check 4.2.31 because 
@ -262,19 +307,26 @@ void RMFT2::setTurnoutHiddenState(Turnout * t) {
  t->setHidden(GETFLASH(getTurnoutDescription(t->getId()))==0x01);     
 }
 #ifndef IO_NO_HAL
 void RMFT2::setTurntableHiddenState(Turntable * tto) {
  tto->setHidden(GETFLASH(getTurntableDescription(tto->getId()))==0x01);
 }
 #endif
 char RMFT2::getRouteType(int16_t id) {
  for (int16_t i=0;;i+=2) {
    int16_t rid= GETHIGHFLASHW(routeIdList,i);
    if (rid==INT16_MAX) break;
    if (rid==id) return 'R';
    if (rid==0) break;
  }
  for (int16_t i=0;;i+=2) {
    int16_t rid= GETHIGHFLASHW(automationIdList,i);
    if (rid==INT16_MAX) break;
    if (rid==id) return 'A';
    if (rid==0) break;
  }
  return 'X';
 }
 // This filter intercepts <> commands to do the following:
 // - Implement RMFT specific commands/diagnostics
 // - Reject/modify JMRI commands that would interfere with RMFT processing
@ -294,13 +346,65 @@ void RMFT2::ComandFilter(Print * stream, byte & opcode, byte & paramCount, int16
    reject=!parseSlash(stream,paramCount,p);
    opcode=0;
    break;
  case 'L':
    if (compileFeatures & FEATURE_LCC) { 
      // This entire code block is compiled out if LLC macros not used 
    if (paramCount==0) {  //<L>  LCC adapter introducing self
      LCCSerial=stream;   // now we know where to send events we raise
      // loop through all possible sent events 
      for (int progCounter=0;; SKIPOP) {
        byte opcode=GET_OPCODE;
        if (opcode==OPCODE_ENDEXRAIL) break;
        if (opcode==OPCODE_LCC)  StringFormatter::send(stream,F("<LS x%h>\n"),getOperand(progCounter,0));   
        if (opcode==OPCODE_LCCX) { // long form LCC
           StringFormatter::send(stream,F("<LS x%h%h%h%h>\n"),
                 getOperand(progCounter,1),
                 getOperand(progCounter,2),
                 getOperand(progCounter,3),
                 getOperand(progCounter,0)
                 );        
        }}
      // we stream the hex events we wish to listen to
      // and at the same time build the event index looku.
      int eventIndex=0;
      for (int progCounter=0;; SKIPOP) {
        byte opcode=GET_OPCODE;
        if (opcode==OPCODE_ENDEXRAIL) break;
        if (opcode==OPCODE_ONLCC) {
           onLCCLookup[eventIndex]=progCounter; // TODO skip...
           StringFormatter::send(stream,F("<LL %d x%h%h%h:%h>\n"),
                 eventIndex,
                 getOperand(progCounter,1),
                 getOperand(progCounter,2),
                 getOperand(progCounter,3),
                 getOperand(progCounter,0)
                 );   
           eventIndex++;      
        }
      }
      StringFormatter::send(stream,F("<LR>\n")); // Ready to rumble
      opcode=0;
      break;
    }
    if (paramCount==1) {  // <L eventid> LCC event arrived from adapter
        int16_t eventid=p[0];
        reject=eventid<0 || eventid>=countLCCLookup;
        if (!reject)  startNonRecursiveTask(F("LCC"),eventid,onLCCLookup[eventid]);
        opcode=0;
    }
    }
    break; 
  default:  // other commands pass through
    break;
  }
  if (reject) {
    opcode=0;
-    StringFormatter::send(stream,F("<X>"));
+    StringFormatter::send(stream,F("<X>\n"));
  }
 }
@ -328,17 +432,19 @@ bool RMFT2::parseSlash(Print * stream, byte & paramCount, int16_t p[]) {
 	      if (flag & LATCH_FLAG) StringFormatter::send(stream,F(" LATCHED"));
      }
    }
    // do the signals
    // flags[n] represents the state of the nth signal in the table 
    for (int sigslot=0;;sigslot++) {
      VPIN sigid=GETHIGHFLASHW(RMFT2::SignalDefinitions,sigslot*8);
      if (sigid==0) break; // end of signal list 
      byte flag=flags[sigslot] & SIGNAL_MASK; // obtain signal flags for this id
      StringFormatter::send(stream,F("\n%S[%d]"), 
        (flag == SIGNAL_RED)? F("RED") : (flag==SIGNAL_GREEN) ? F("GREEN") : F("AMBER"),
        sigid & SIGNAL_ID_MASK); 
    } 
    if (compileFeatures & FEATURE_SIGNAL) {
      // do the signals
      // flags[n] represents the state of the nth signal in the table 
      for (int sigslot=0;;sigslot++) {
        VPIN sigid=GETHIGHFLASHW(RMFT2::SignalDefinitions,sigslot*8);
        if (sigid==0) break; // end of signal list 
        byte flag=flags[sigslot] & SIGNAL_MASK; // obtain signal flags for this id
        StringFormatter::send(stream,F("\n%S[%d]"), 
          (flag == SIGNAL_RED)? F("RED") : (flag==SIGNAL_GREEN) ? F("GREEN") : F("AMBER"),
          sigid & SIGNAL_ID_MASK); 
      } 
    }
    StringFormatter::send(stream,F(" *>\n"));
    return true;
  }
@ -597,6 +703,14 @@ void RMFT2::loop2() {
    Turnout::setClosed(operand, true);
    break;
 #ifndef IO_NO_HAL
  case OPCODE_ROTATE:
    uint8_t activity;
    activity=getOperand(2);
    Turntable::setPosition(operand,getOperand(1),activity);
    break;
 #endif
  case OPCODE_REV:
    forward = false;
    driveLoco(operand);
@ -608,6 +722,7 @@ void RMFT2::loop2() {
      break;
  case OPCODE_SPEED:
    forward=DCC::getThrottleDirection(loco)^invert;
    driveLoco(operand);
    break;
@ -682,6 +797,16 @@ void RMFT2::loop2() {
    if (millis()-waitAfter < 500 ) return;
    break;
  case OPCODE_AFTEROVERLOAD: // waits for the power to be turned back on - either by power routine or button
    if (!TrackManager::isPowerOn(operand)) {
      // reset timer to half a second and keep waiting
      waitAfter=millis();
      delayMe(50);
      return;
    }
    if (millis()-waitAfter < 500 ) return;
    break;
  case OPCODE_LATCH:
    setFlag(operand,LATCH_FLAG);
    break;
@ -713,6 +838,20 @@ void RMFT2::loop2() {
    CommandDistributor::broadcastPower();
    break;
  case OPCODE_SET_POWER:
      // operand is TRACK_POWER , trackid
        //byte thistrack=getOperand(1);
        switch (operand) {
          case TRACK_POWER_0:
            TrackManager::setTrackPower(TrackManager::isProg(getOperand(1)), false, POWERMODE::OFF, getOperand(1));
          break;
          case TRACK_POWER_1:
            TrackManager::setTrackPower(TrackManager::isProg(getOperand(1)), false, POWERMODE::ON, getOperand(1));
          break;
        }
    break;
  case OPCODE_SET_TRACK:
      // operand is trackmode<<8 | track id
      // If DC/DCX use  my loco for DC address 
@ -786,6 +925,12 @@ void RMFT2::loop2() {
    skipIf=Turnout::isThrown(operand);
    break;
 #ifndef IO_NO_HAL
  case OPCODE_IFTTPOSITION: // do block if turntable at this position
    skipIf=Turntable::getPosition(operand)!=(int)getOperand(1);
    break;
 #endif
  case OPCODE_ENDIF:
    break;
@ -881,18 +1026,13 @@ void RMFT2::loop2() {
    while(loopTask) loopTask->kill(F("KILLALL"));
    return;
 #ifndef DISABLE_PROG
  case OPCODE_JOIN:
    TrackManager::setPower(POWERMODE::ON);
    TrackManager::setJoin(true);
    CommandDistributor::broadcastPower();
    break;
  case OPCODE_POWERON:
    TrackManager::setMainPower(POWERMODE::ON);
    TrackManager::setJoin(false);
    CommandDistributor::broadcastPower();
    break;
  case OPCODE_UNJOIN:
    TrackManager::setJoin(false);
    CommandDistributor::broadcastPower();
@ -918,6 +1058,13 @@ void RMFT2::loop2() {
    forward=true;
    invert=false;
    break;
 #endif
  case OPCODE_POWERON:
    TrackManager::setMainPower(POWERMODE::ON);
    TrackManager::setJoin(false);
    CommandDistributor::broadcastPower();
    break;
  case OPCODE_START:
    {
@ -945,6 +1092,20 @@ void RMFT2::loop2() {
    }
    break;
  case OPCODE_LCC:  // short form LCC
      if ((compileFeatures & FEATURE_LCC) && LCCSerial) 
          StringFormatter::send(LCCSerial,F("<L x%h>"),(uint16_t)operand);
       break; 
  case OPCODE_LCCX: // long form LCC
       if ((compileFeatures & FEATURE_LCC) && LCCSerial)
            StringFormatter::send(LCCSerial,F("<L x%h%h%h%h>\n"),
                 getOperand(progCounter,1),
                 getOperand(progCounter,2),
                 getOperand(progCounter,3),
                 getOperand(progCounter,0)
                 );    
        break;  
  case OPCODE_SERVO: // OPCODE_SERVO,V(vpin),OPCODE_PAD,V(position),OPCODE_PAD,V(profile),OPCODE_PAD,V(duration)
    IODevice::writeAnalogue(operand,getOperand(1),getOperand(2),getOperand(3));
@ -957,6 +1118,15 @@ void RMFT2::loop2() {
    }
    break;
 #ifndef IO_NO_HAL
  case OPCODE_WAITFORTT:  // OPCODE_WAITFOR,V(turntable_id)
    if (Turntable::ttMoving(operand)) {
      delayMe(100);
      return;
    }
    break;
 #endif
  case OPCODE_PRINT:
    printMessage(operand);
    break;
@ -973,6 +1143,7 @@ void RMFT2::loop2() {
  case OPCODE_SERVOTURNOUT: // Turnout definition ignored at runtime
  case OPCODE_PINTURNOUT: // Turnout definition ignored at runtime
  case OPCODE_ONCLOSE: // Turnout event catchers ignored here
  case OPCODE_ONLCC:   // LCC event catchers ignored here 
  case OPCODE_ONTHROW:
  case OPCODE_ONACTIVATE: // Activate event catchers ignored here
  case OPCODE_ONDEACTIVATE:
@ -981,6 +1152,13 @@ void RMFT2::loop2() {
  case OPCODE_ONGREEN:
  case OPCODE_ONCHANGE:
  case OPCODE_ONTIME:
 #ifndef IO_NO_HAL
  case OPCODE_DCCTURNTABLE: // Turntable definition ignored at runtime
  case OPCODE_EXTTTURNTABLE:  // Turntable definition ignored at runtime
  case OPCODE_TTADDPOSITION:  // Turntable position definition ignored at runtime
  case OPCODE_ONROTATE:
 #endif
  case OPCODE_ONOVERLOAD:
    break;
@ -1035,6 +1213,7 @@ int16_t RMFT2::getSignalSlot(int16_t id) {
 }
 /* static */ void RMFT2::doSignal(int16_t id,char rag) {
  if (!(compileFeatures & FEATURE_SIGNAL)) return; // dont compile code below
  if (diag) DIAG(F(" doSignal %d %x"),id,rag);
  // Schedule any event handler for this signal change.
@ -1102,6 +1281,7 @@ int16_t RMFT2::getSignalSlot(int16_t id) {
 }
 /* static */ bool RMFT2::isSignal(int16_t id,char rag) {
  if (!(compileFeatures & FEATURE_SIGNAL)) return false; 
  int16_t sigslot=getSignalSlot(id);
  if (sigslot<0) return false; 
  return (flags[sigslot] & SIGNAL_MASK) == rag;
@ -1125,17 +1305,39 @@ void RMFT2::changeEvent(int16_t vpin, bool change) {
  if (change)  handleEvent(F("CHANGE"),onChangeLookup,vpin);
 }
 #ifndef IO_NO_HAL
 void RMFT2::rotateEvent(int16_t turntableId, bool change) {
  // Hunt or an ONROTATE for this turntable
  if (change) handleEvent(F("ROTATE"),onRotateLookup,turntableId);
 }
 #endif
 void RMFT2::clockEvent(int16_t clocktime, bool change) {
  // Hunt for an ONTIME for this time
  if (Diag::CMD)
   DIAG(F("Looking for clock event at : %d"), clocktime);
-  if (change)  handleEvent(F("CLOCK"),onClockLookup,clocktime);
+  if (change) {
    handleEvent(F("CLOCK"),onClockLookup,clocktime);
    handleEvent(F("CLOCK"),onClockLookup,25*60+clocktime%60);
  }
 } 
 void RMFT2::powerEvent(int16_t track, bool overload) {
  // Hunt for an ONOVERLOAD for this item
  if (Diag::CMD)
   DIAG(F("Looking for Power event on track : %c"), track);
  if (overload) {
    handleEvent(F("POWER"),onOverloadLookup,track);
  }
 }
 void RMFT2::handleEvent(const FSH* reason,LookList* handlers, int16_t id) {
  int pc= handlers->find(id);
-  if (pc<0) return;
+  if (pc>=0) startNonRecursiveTask(reason,id,pc);
 }
 void RMFT2::startNonRecursiveTask(const FSH* reason, int16_t id,int pc) {  
  // Check we dont already have a task running this handler
  RMFT2 * task=loopTask;
  while(task) {
@ -1237,7 +1439,10 @@ void RMFT2::thrungeString(uint32_t strfar, thrunger mode, byte id) {
      DCCEXParser::parseOne(&USB_SERIAL,(byte*)buffer->getString(),NULL);
      break;
    case thrunge_broadcast:
-  // TODO     CommandDistributor::broadcastText(buffer->getString());
+      CommandDistributor::broadcastRaw(CommandDistributor::COMMAND_TYPE,buffer->getString());
      break;
    case thrunge_withrottle:
      CommandDistributor::broadcastRaw(CommandDistributor::WITHROTTLE_TYPE,buffer->getString());
      break;
    case thrunge_lcd:
         LCD(id,F("%s"),buffer->getString());
--- a/EXRAIL2.h
+++ b/EXRAIL2.h
@ -1,6 +1,7 @@
 /*
 *  © 2021 Neil McKechnie
 *  © 2020-2022 Chris Harlow
 *  © 2022-2023 Colin Murdoch
 *  © 2023 Harald Barth
 *  All rights reserved.
 *  
@ -24,6 +25,7 @@
 #include "FSH.h"
 #include "IODevice.h"
 #include "Turnouts.h"
 #include "Turntables.h"
 // The following are the operation codes (or instructions) for a kind of virtual machine.
 // Each instruction is normally 3 bytes long with an operation code followed by a parameter.
@ -34,7 +36,8 @@
 enum OPCODE : byte {OPCODE_THROW,OPCODE_CLOSE,
             OPCODE_FWD,OPCODE_REV,OPCODE_SPEED,OPCODE_INVERT_DIRECTION,
             OPCODE_RESERVE,OPCODE_FREE,
-             OPCODE_AT,OPCODE_AFTER,OPCODE_AUTOSTART,
+             OPCODE_AT,OPCODE_AFTER,
             OPCODE_AFTEROVERLOAD,OPCODE_AUTOSTART,
             OPCODE_ATGTE,OPCODE_ATLT,
             OPCODE_ATTIMEOUT1,OPCODE_ATTIMEOUT2,
             OPCODE_LATCH,OPCODE_UNLATCH,OPCODE_SET,OPCODE_RESET,
@ -44,7 +47,10 @@ enum OPCODE : byte {OPCODE_THROW,OPCODE_CLOSE,
             OPCODE_RED,OPCODE_GREEN,OPCODE_AMBER,OPCODE_DRIVE,
             OPCODE_SERVO,OPCODE_SIGNAL,OPCODE_TURNOUT,OPCODE_WAITFOR,
             OPCODE_PAD,OPCODE_FOLLOW,OPCODE_CALL,OPCODE_RETURN,
-             OPCODE_JOIN,OPCODE_UNJOIN,OPCODE_READ_LOCO1,OPCODE_READ_LOCO2,OPCODE_POM,
+#ifndef DISABLE_PROG
             OPCODE_JOIN,OPCODE_UNJOIN,OPCODE_READ_LOCO1,OPCODE_READ_LOCO2,
 #endif
             OPCODE_POM,
             OPCODE_START,OPCODE_SETLOCO,OPCODE_SENDLOCO,OPCODE_FORGET,
             OPCODE_PAUSE, OPCODE_RESUME,OPCODE_POWEROFF,OPCODE_POWERON,
             OPCODE_ONCLOSE, OPCODE_ONTHROW, OPCODE_SERVOTURNOUT, OPCODE_PINTURNOUT,
@ -53,11 +59,15 @@ enum OPCODE : byte {OPCODE_THROW,OPCODE_CLOSE,
             OPCODE_ROSTER,OPCODE_KILLALL,
             OPCODE_ROUTE,OPCODE_AUTOMATION,OPCODE_SEQUENCE,
             OPCODE_ENDTASK,OPCODE_ENDEXRAIL,
-             OPCODE_SET_TRACK,
+             OPCODE_SET_TRACK,OPCODE_SET_POWER,
             OPCODE_ONRED,OPCODE_ONAMBER,OPCODE_ONGREEN,
             OPCODE_ONCHANGE,
             OPCODE_ONCLOCKTIME,
             OPCODE_ONTIME,
             OPCODE_TTADDPOSITION,OPCODE_DCCTURNTABLE,OPCODE_EXTTTURNTABLE,
             OPCODE_ONROTATE,OPCODE_ROTATE,OPCODE_WAITFORTT,
             OPCODE_LCC,OPCODE_LCCX,OPCODE_ONLCC,
             OPCODE_ONOVERLOAD,
             // OPcodes below this point are skip-nesting IF operations
             // placed here so that they may be skipped as a group
@ -70,19 +80,25 @@ enum OPCODE : byte {OPCODE_THROW,OPCODE_CLOSE,
             OPCODE_IFRANDOM,OPCODE_IFRESERVE,
             OPCODE_IFCLOSED,OPCODE_IFTHROWN,
             OPCODE_IFRE,
-             OPCODE_IFLOCO
+             OPCODE_IFLOCO,
             OPCODE_IFTTPOSITION
             };
 // Ensure thrunge_lcd is put last as there may be more than one display, 
 // sequentially numbered from thrunge_lcd.
 enum thrunger: byte {
-  thrunge_print, thrunge_broadcast, thrunge_serial,thrunge_parse,
+  thrunge_print, thrunge_broadcast, thrunge_withrottle,
  thrunge_serial,thrunge_parse,
  thrunge_serial1, thrunge_serial2, thrunge_serial3,
  thrunge_serial4, thrunge_serial5, thrunge_serial6,
  thrunge_lcn, 
  thrunge_lcd,  // Must be last!!
  };
  // Flag bits for compile time features.
  static const byte FEATURE_SIGNAL= 0x80;
  static const byte FEATURE_LCC   = 0x40;
  static const byte FEATURE_ROSTER= 0x20;
  // Flag bits for status of hardware and TPL
@ -125,6 +141,8 @@ class LookList {
    static void activateEvent(int16_t addr, bool active);
    static void changeEvent(int16_t id, bool change);
    static void clockEvent(int16_t clocktime, bool change);
    static void rotateEvent(int16_t id, bool change);
    static void powerEvent(int16_t track, bool overload);
    static const int16_t SERVO_SIGNAL_FLAG=0x4000;
    static const int16_t ACTIVE_HIGH_SIGNAL_FLAG=0x2000;
    static const int16_t DCC_SIGNAL_FLAG=0x1000;
@ -139,6 +157,8 @@ class LookList {
  static const FSH *  getTurnoutDescription(int16_t id);
  static const FSH *  getRosterName(int16_t id);
  static const FSH *  getRosterFunctions(int16_t id);
  static const FSH *  getTurntableDescription(int16_t id);
  static const FSH *  getTurntablePositionDescription(int16_t turntableId, uint8_t positionId);
 private: 
    static void ComandFilter(Print * stream, byte & opcode, byte & paramCount, int16_t p[]);
@ -151,10 +171,14 @@ private:
    static bool isSignal(int16_t id,char rag); 
    static int16_t getSignalSlot(int16_t id);
    static void setTurnoutHiddenState(Turnout * t);
    #ifndef IO_NO_HAL
    static void setTurntableHiddenState(Turntable * tto);
    #endif
    static LookList* LookListLoader(OPCODE op1,
                      OPCODE op2=OPCODE_ENDEXRAIL,OPCODE op3=OPCODE_ENDEXRAIL);
    static void handleEvent(const FSH* reason,LookList* handlers, int16_t id);
    static uint16_t getOperand(int progCounter,byte n);
    static void startNonRecursiveTask(const FSH* reason, int16_t id,int pc);
    static RMFT2 * loopTask;
    static RMFT2 * pausingTask;
    void delayMe(long millisecs);
@ -173,6 +197,7 @@ private:
   static const  HIGHFLASH  byte RouteCode[];
   static const  HIGHFLASH  int16_t SignalDefinitions[];
   static byte flags[MAX_FLAGS];
   static Print * LCCSerial;
   static LookList * sequenceLookup;
   static LookList * onThrowLookup;
   static LookList * onCloseLookup;
@ -183,6 +208,14 @@ private:
   static LookList * onGreenLookup;
   static LookList * onChangeLookup;
   static LookList * onClockLookup;
 #ifndef IO_NO_HAL
   static LookList * onRotateLookup;
 #endif
   static LookList * onOverloadLookup;
   static const int countLCCLookup;
   static int onLCCLookup[];
   static const byte compileFeatures;
  // Local variables - exist for each instance/task 
    RMFT2 *next;   // loop chain 
--- a/EXRAIL2MacroReset.h
+++ b/EXRAIL2MacroReset.h
@ -1,5 +1,6 @@
 /*
 *  © 2020-2022 Chris Harlow. All rights reserved.
 *  © 2022-2023 Colin Murdoch
 *  © 2023 Harald Barth
 *  
 *  This file is part of CommandStation-EX
@ -26,6 +27,7 @@
 #undef ACTIVATE
 #undef ACTIVATEL
 #undef AFTER
 #undef AFTEROVERLOAD
 #undef ALIAS
 #undef AMBER
 #undef ANOUT
@ -39,6 +41,7 @@
 #undef CALL 
 #undef CLOSE 
 #undef DCC_SIGNAL
 #undef DCC_TURNTABLE
 #undef DEACTIVATE
 #undef DEACTIVATEL
 #undef DELAY
@ -52,6 +55,7 @@
 #undef ENDTASK
 #undef ESTOP
 #undef EXRAIL
 #undef EXTT_TURNTABLE
 #undef FADE
 #undef FOFF
 #undef FOLLOW 
@ -74,6 +78,7 @@
 #undef IFRESERVE
 #undef IFTHROWN
 #undef IFTIMEOUT
 #undef IFTTPOSITION
 #undef IFRE
 #undef INVERT_DIRECTION 
 #undef JOIN 
@ -81,6 +86,8 @@
 #undef LATCH 
 #undef LCD 
 #undef SCREEN
 #undef LCC 
 #undef LCCX 
 #undef LCN 
 #undef MOVETT
 #undef ONACTIVATE
@ -89,17 +96,23 @@
 #undef ONDEACTIVATE
 #undef ONDEACTIVATEL 
 #undef ONCLOSE
 #undef ONLCC
 #undef ONTIME
 #undef ONCLOCKTIME
 #undef ONCLOCKMINS
 #undef ONOVERLOAD
 #undef ONGREEN
 #undef ONRED
 #undef ONROTATE
 #undef ONTHROW 
 #undef ONCHANGE
 #undef PARSE
 #undef PAUSE
 #undef PIN_TURNOUT 
 #undef PRINT
 #ifndef DISABLE_PROG
 #undef POM
 #endif
 #undef POWEROFF
 #undef POWERON
 #undef READ_LOCO 
@ -110,6 +123,8 @@
 #undef RETURN 
 #undef REV
 #undef ROSTER
 #undef ROTATE
 #undef ROTATE_DCC
 #undef ROUTE
 #undef SENDLOCO 
 #undef SEQUENCE 
@ -126,6 +141,7 @@
 #undef SERVO_SIGNAL
 #undef SET
 #undef SET_TRACK
 #undef SET_POWER
 #undef SETLOCO 
 #undef SIGNAL 
 #undef SIGNALH 
@ -133,12 +149,18 @@
 #undef START 
 #undef STOP 
 #undef THROW
 #undef TT_ADDPOSITION
 #undef TURNOUT 
 #undef TURNOUTL
 #undef UNJOIN
 #undef UNLATCH 
 #undef VIRTUAL_SIGNAL
 #undef VIRTUAL_TURNOUT
 #undef WAITFOR
 #ifndef IO_NO_HAL
 #undef WAITFORTT
 #endif
 #undef WITHROTTLE
 #undef XFOFF
 #undef XFON
@ -146,6 +168,7 @@
 #define ACTIVATE(addr,subaddr)
 #define ACTIVATEL(addr)
 #define AFTER(sensor_id)
 #define AFTEROVERLOAD(track_id)
 #define ALIAS(name,value...)
 #define AMBER(signal_id)
 #define ANOUT(vpin,value,param1,param2)
@ -159,6 +182,7 @@
 #define CALL(route) 
 #define CLOSE(id) 
 #define DCC_SIGNAL(id,add,subaddr)
 #define DCC_TURNTABLE(id,home,description)
 #define DEACTIVATE(addr,subaddr)
 #define DEACTIVATEL(addr)
 #define DELAY(mindelay)
@ -172,6 +196,7 @@
 #define ENDTASK
 #define ESTOP 
 #define EXRAIL
 #define EXTT_TURNTABLE(id,vpin,home,description)
 #define FADE(pin,value,ms)
 #define FOFF(func)
 #define FOLLOW(route) 
@ -194,11 +219,14 @@
 #define IFTHROWN(turnout_id) 
 #define IFRESERVE(block)
 #define IFTIMEOUT
 #define IFTTPOSITION(turntable_id,position)
 #define IFRE(sensor_id,value)
 #define INVERT_DIRECTION 
 #define JOIN 
 #define KILLALL
 #define LATCH(sensor_id)
 #define LCC(eventid) 
 #define LCCX(senderid,eventid) 
 #define LCD(row,msg)
 #define SCREEN(display,row,msg)
 #define LCN(msg) 
@ -208,18 +236,24 @@
 #define ONAMBER(signal_id) 
 #define ONTIME(value)
 #define ONCLOCKTIME(hours,mins)
 #define ONCLOCKMINS(mins)
 #define ONOVERLOAD(track_id)
 #define ONDEACTIVATE(addr,subaddr)
 #define ONDEACTIVATEL(linear) 
 #define ONCLOSE(turnout_id)
 #define ONLCC(sender,event)
 #define ONGREEN(signal_id) 
 #define ONRED(signal_id)
 #define ONROTATE(turntable_id)
 #define ONTHROW(turnout_id) 
 #define ONCHANGE(sensor_id)
 #define PAUSE
 #define PIN_TURNOUT(id,pin,description...) 
 #define PRINT(msg) 
 #define PARSE(msg)
 #ifndef DISABLE_PROG
 #define POM(cv,value)
 #endif
 #define POWEROFF
 #define POWERON
 #define READ_LOCO 
@ -229,8 +263,10 @@
 #define RESUME 
 #define RETURN 
 #define REV(speed) 
-#define ROUTE(id,description)
+#define ROTATE(turntable_id,position,activity)
 #define ROTATE_DCC(turntable_id,position)
 #define ROSTER(cab,name,funcmap...)
 #define ROUTE(id,description)
 #define SENDLOCO(cab,route) 
 #define SEQUENCE(id) 
 #define SERIAL(msg) 
@ -246,6 +282,7 @@
 #define SERVO_TURNOUT(id,pin,activeAngle,inactiveAngle,profile,description...) 
 #define SET(pin) 
 #define SET_TRACK(track,mode)
 #define SET_POWER(track,onoff)
 #define SETLOCO(loco) 
 #define SIGNAL(redpin,amberpin,greenpin) 
 #define SIGNALH(redpin,amberpin,greenpin) 
@ -253,12 +290,18 @@
 #define START(route) 
 #define STOP 
 #define THROW(id)
 #define TT_ADDPOSITION(turntable_id,position,value,angle,description...)
 #define TURNOUT(id,addr,subaddr,description...) 
 #define TURNOUTL(id,addr,description...) 
 #define UNJOIN 
 #define UNLATCH(sensor_id) 
 #define VIRTUAL_SIGNAL(id) 
 #define VIRTUAL_TURNOUT(id,description...) 
 #define WAITFOR(pin)
 #ifndef IO_NO_HAL
 #define WAITFORTT(turntable_id)
 #endif
 #define WITHROTTLE(msg)
 #define XFOFF(cab,func)
 #define XFON(cab,func)
 #endif
--- a/EXRAILMacros.h
+++ b/EXRAILMacros.h
@ -1,6 +1,7 @@
 /*
 *  © 2021 Neil McKechnie
 *  © 2020-2022 Chris Harlow
 *  © 2022-2023 Colin Murdoch
 *  © 2023 Harald Barth
 *  All rights reserved.
 *  
@ -53,6 +54,8 @@
 // helper macro for turnout descriptions, creates NULL for missing description
 #define O_DESC(id, desc) case id: return ("" desc)[0]?F("" desc):NULL;
 // helper macro for turntable descriptions, creates NULL for missing description
 #define T_DESC(tid,pid,desc) if(turntableId==tid && positionId==pid) return ("" desc)[0]?F("" desc):NULL;
 // helper macro for turnout description as HIDDEN 
 #define HIDDEN "\x01"
@ -60,6 +63,11 @@
 // (10#mins)%100)
 #define STRIP_ZERO(value) 10##value%100
 // These constants help EXRAIL macros convert Track Power e.g. SET_POWER(A ON|OFF).
 //const byte TRACK_POWER_0=0, TRACK_POWER_OFF=0;    
 //const byte TRACK_POWER_1=1, TRACK_POWER_ON=1;   
 // Pass 1 Implements aliases 
 #include "EXRAIL2MacroReset.h"
 #undef ALIAS
@ -67,6 +75,7 @@
 #include "myAutomation.h"
 // Pass 1h Implements HAL macro by creating exrailHalSetup function
 // Also allows creating EXTurntable object
 #include "EXRAIL2MacroReset.h"
 #undef HAL
 #define HAL(haltype,params...)  haltype::create(params);
@ -74,20 +83,44 @@ void exrailHalSetup() {
   #include "myAutomation.h"
 }
 // Pass 1c detect compile time featurtes
 #include "EXRAIL2MacroReset.h"
 #undef SIGNAL
 #define SIGNAL(redpin,amberpin,greenpin) | FEATURE_SIGNAL 
 #undef SIGNALH
 #define SIGNALH(redpin,amberpin,greenpin) | FEATURE_SIGNAL 
 #undef SERVO_SIGNAL
 #define SERVO_SIGNAL(vpin,redval,amberval,greenval) | FEATURE_SIGNAL 
 #undef DCC_SIGNAL
 #define DCC_SIGNAL(id,addr,subaddr) | FEATURE_SIGNAL
 #undef VIRTUAL_SIGNAL
 #define VIRTUAL_SIGNAL(id) | FEATURE_SIGNAL
 #undef LCC
 #define LCC(eventid)  | FEATURE_LCC
 #undef LCCX
 #define LCCX(senderid,eventid) | FEATURE_LCC 
 #undef ONLCC
 #define ONLCC(senderid,eventid) | FEATURE_LCC
 const byte RMFT2::compileFeatures = 0
   #include "myAutomation.h"
 ;
 // Pass 2 create throttle route list 
 #include "EXRAIL2MacroReset.h"
 #undef ROUTE
 #define ROUTE(id, description) id,
 const int16_t HIGHFLASH RMFT2::routeIdList[]= {
    #include "myAutomation.h"
-    0}; 
+    INT16_MAX};
 // Pass 2a create throttle automation list 
 #include "EXRAIL2MacroReset.h"
 #undef AUTOMATION
 #define AUTOMATION(id, description) id,
 const int16_t HIGHFLASH RMFT2::automationIdList[]= {
    #include "myAutomation.h"
-    0}; 
+    INT16_MAX};
 // Pass 3 Create route descriptions:
 #undef ROUTE
@ -152,6 +185,8 @@ const int StringMacroTracker1=__COUNTER__;
         lcdid=id;\
         break;\
      } 
 #undef WITHROTTLE
 #define WITHROTTLE(msg) THRUNGE(msg,thrunge_withrottle)
 void  RMFT2::printMessage(uint16_t id) { 
  thrunger tmode;
@ -184,10 +219,35 @@ const FSH * RMFT2::getTurnoutDescription(int16_t turnoutid) {
     return NULL;
 }
 // Pass to get turntable descriptions (optional)
 #include "EXRAIL2MacroReset.h"
 #undef DCC_TURNTABLE
 #define DCC_TURNTABLE(id,home,description...) O_DESC(id,description)
 #undef EXTT_TURNTABLE
 #define EXTT_TURNTABLE(id,vpin,home,description...) O_DESC(id,description)
 const FSH * RMFT2::getTurntableDescription(int16_t turntableId) {
   switch (turntableId) {
      #include "myAutomation.h"
   default:break;
   }
   return NULL;
 }
 // Pass to get turntable position descriptions (optional)
 #include "EXRAIL2MacroReset.h"
 #undef TT_ADDPOSITION
 #define TT_ADDPOSITION(turntable_id,position,value,home,description...) T_DESC(turntable_id,position,description)
 const FSH * RMFT2::getTurntablePositionDescription(int16_t turntableId, uint8_t positionId) {
   #include "myAutomation.h"
   return NULL;
 }
 // Pass 6: Roster IDs (count)
 #include "EXRAIL2MacroReset.h"
 #undef ROSTER
-#define ROSTER(cabid,name,funcmap...) +1
+#define ROSTER(cabid,name,funcmap...) +(cabid <= 0 ? 0 : 1)
 const byte RMFT2::rosterNameCount=0
   #include "myAutomation.h"
   ;
@ -198,7 +258,7 @@ const byte RMFT2::rosterNameCount=0
 #define ROSTER(cabid,name,funcmap...) cabid,
 const int16_t HIGHFLASH  RMFT2::rosterIdList[]={
   #include "myAutomation.h"
-   0};
+   INT16_MAX};
 // Pass 7: Roster names getter
 #include "EXRAIL2MacroReset.h"
@ -220,7 +280,7 @@ const FSH * RMFT2::getRosterFunctions(int16_t id) {
      #include "myAutomation.h"
   default: break; 
   }   
-   return F("");
+   return NULL;
 } 
 // Pass 8 Signal definitions
@ -240,6 +300,16 @@ const  HIGHFLASH  int16_t RMFT2::SignalDefinitions[] = {
    #include "myAutomation.h"
    0,0,0,0 };
 // Pass 9 ONLCC counter and lookup array
 #include "EXRAIL2MacroReset.h"
 #undef ONLCC
 #define ONLCC(sender,event) +1 
 const int RMFT2::countLCCLookup=0
 #include "myAutomation.h"
 ;
 int RMFT2::onLCCLookup[RMFT2::countLCCLookup];
 // Last Pass : create main routes table
 // Only undef the macros, not dummy them.  
 #define  RMFT2_UNDEF_ONLY
@ -253,6 +323,7 @@ const  HIGHFLASH  int16_t RMFT2::SignalDefinitions[] = {
 #define ACTIVATE(addr,subaddr) OPCODE_DCCACTIVATE,V(addr<<3 | subaddr<<1 | 1),
 #define ACTIVATEL(addr) OPCODE_DCCACTIVATE,V((addr+3)<<1 | 1),
 #define AFTER(sensor_id) OPCODE_AT,V(sensor_id),OPCODE_AFTER,V(sensor_id),
 #define AFTEROVERLOAD(track_id) OPCODE_AFTEROVERLOAD,V(TRACK_NUMBER_##track_id),
 #define ALIAS(name,value...) 
 #define AMBER(signal_id) OPCODE_AMBER,V(signal_id),
 #define ANOUT(vpin,value,param1,param2) OPCODE_SERVO,V(vpin),OPCODE_PAD,V(value),OPCODE_PAD,V(param1),OPCODE_PAD,V(param2),
@ -265,6 +336,9 @@ const  HIGHFLASH  int16_t RMFT2::SignalDefinitions[] = {
 #define BROADCAST(msg) PRINT(msg)
 #define CALL(route) OPCODE_CALL,V(route),
 #define CLOSE(id)  OPCODE_CLOSE,V(id),
 #ifndef IO_NO_HAL
 #define DCC_TURNTABLE(id,home,description...) OPCODE_DCCTURNTABLE,V(id),OPCODE_PAD,V(home),
 #endif
 #define DEACTIVATE(addr,subaddr) OPCODE_DCCACTIVATE,V(addr<<3 | subaddr<<1),
 #define DEACTIVATEL(addr) OPCODE_DCCACTIVATE,V((addr+3)<<1),
 #define DELAY(ms) ms<30000?OPCODE_DELAYMS:OPCODE_DELAY,V(ms/(ms<30000?1L:100L)),
@ -279,6 +353,9 @@ const  HIGHFLASH  int16_t RMFT2::SignalDefinitions[] = {
 #define ENDTASK OPCODE_ENDTASK,0,0,
 #define ESTOP OPCODE_SPEED,V(1), 
 #define EXRAIL
 #ifndef IO_NO_HAL
 #define EXTT_TURNTABLE(id,vpin,home,description...) OPCODE_EXTTTURNTABLE,V(id),OPCODE_PAD,V(vpin),OPCODE_PAD,V(home),
 #endif
 #define FADE(pin,value,ms) OPCODE_SERVO,V(pin),OPCODE_PAD,V(value),OPCODE_PAD,V(PCA9685::ProfileType::UseDuration|PCA9685::NoPowerOff),OPCODE_PAD,V(ms/100L),
 #define FOFF(func) OPCODE_FOFF,V(func),
 #define FOLLOW(route) OPCODE_FOLLOW,V(route),
@ -301,11 +378,19 @@ const  HIGHFLASH  int16_t RMFT2::SignalDefinitions[] = {
 #define IFRESERVE(block) OPCODE_IFRESERVE,V(block),
 #define IFTHROWN(turnout_id) OPCODE_IFTHROWN,V(turnout_id),
 #define IFTIMEOUT OPCODE_IFTIMEOUT,0,0,
 #ifndef IO_NO_HAL
 #define IFTTPOSITION(id,position) OPCODE_IFTTPOSITION,V(id),OPCODE_PAD,V(position),
 #endif
 #define IFRE(sensor_id,value) OPCODE_IFRE,V(sensor_id),OPCODE_PAD,V(value),
 #define INVERT_DIRECTION OPCODE_INVERT_DIRECTION,0,0,
 #define JOIN OPCODE_JOIN,0,0,
 #define KILLALL OPCODE_KILLALL,0,0,
 #define LATCH(sensor_id) OPCODE_LATCH,V(sensor_id),
 #define LCC(eventid) OPCODE_LCC,V(eventid),
 #define LCCX(sender,event) OPCODE_LCCX,V(event),\
        OPCODE_PAD,V((((uint64_t)sender)>>32)&0xFFFF),\
        OPCODE_PAD,V((((uint64_t)sender)>>16)&0xFFFF),\
        OPCODE_PAD,V((((uint64_t)sender)>>0)&0xFFFF),  
 #define LCD(id,msg) PRINT(msg)
 #define SCREEN(display,id,msg) PRINT(msg)
 #define LCN(msg) PRINT(msg)
@ -314,17 +399,28 @@ const  HIGHFLASH  int16_t RMFT2::SignalDefinitions[] = {
 #define ONACTIVATEL(linear) OPCODE_ONACTIVATE,V(linear+3),
 #define ONAMBER(signal_id) OPCODE_ONAMBER,V(signal_id),
 #define ONCLOSE(turnout_id) OPCODE_ONCLOSE,V(turnout_id),
 #define ONLCC(sender,event) OPCODE_ONLCC,V(event),\
        OPCODE_PAD,V((((uint64_t)sender)>>32)&0xFFFF),\
        OPCODE_PAD,V((((uint64_t)sender)>>16)&0xFFFF),\
        OPCODE_PAD,V((((uint64_t)sender)>>0)&0xFFFF),        
 #define ONTIME(value) OPCODE_ONTIME,V(value),  
 #define ONCLOCKTIME(hours,mins) OPCODE_ONTIME,V((STRIP_ZERO(hours)*60)+STRIP_ZERO(mins)),
 #define ONCLOCKMINS(mins) ONCLOCKTIME(25,mins)
 #define ONOVERLOAD(track_id) OPCODE_ONOVERLOAD,V(TRACK_NUMBER_##track_id),
 #define ONDEACTIVATE(addr,subaddr) OPCODE_ONDEACTIVATE,V(addr<<2|subaddr),
 #define ONDEACTIVATEL(linear) OPCODE_ONDEACTIVATE,V(linear+3),
 #define ONGREEN(signal_id) OPCODE_ONGREEN,V(signal_id),
 #define ONRED(signal_id) OPCODE_ONRED,V(signal_id),
 #ifndef IO_NO_HAL
 #define ONROTATE(id) OPCODE_ONROTATE,V(id),
 #endif
 #define ONTHROW(turnout_id) OPCODE_ONTHROW,V(turnout_id),
 #define ONCHANGE(sensor_id) OPCODE_ONCHANGE,V(sensor_id),
 #define PAUSE OPCODE_PAUSE,0,0,
 #define PIN_TURNOUT(id,pin,description...) OPCODE_PINTURNOUT,V(id),OPCODE_PAD,V(pin),
 #ifndef DISABLE_PROG
 #define POM(cv,value) OPCODE_POM,V(cv),OPCODE_PAD,V(value),
 #endif
 #define POWEROFF OPCODE_POWEROFF,0,0,
 #define POWERON OPCODE_POWERON,0,0,
 #define PRINT(msg) OPCODE_PRINT,V(__COUNTER__ - StringMacroTracker2),
@ -337,6 +433,10 @@ const  HIGHFLASH  int16_t RMFT2::SignalDefinitions[] = {
 #define RETURN OPCODE_RETURN,0,0,
 #define REV(speed) OPCODE_REV,V(speed),
 #define ROSTER(cabid,name,funcmap...)
 #ifndef IO_NO_HAL
 #define ROTATE(id,position,activity) OPCODE_ROTATE,V(id),OPCODE_PAD,V(position),OPCODE_PAD,V(EXTurntable::activity),
 #define ROTATE_DCC(id,position) OPCODE_ROTATE,V(id),OPCODE_PAD,V(position),OPCODE_PAD,V(0),
 #endif
 #define ROUTE(id, description)  OPCODE_ROUTE, V(id), 
 #define SENDLOCO(cab,route) OPCODE_SENDLOCO,V(cab),OPCODE_PAD,V(route),
 #define SEQUENCE(id)  OPCODE_SEQUENCE, V(id), 
@ -353,6 +453,7 @@ const  HIGHFLASH  int16_t RMFT2::SignalDefinitions[] = {
 #define SERVO_TURNOUT(id,pin,activeAngle,inactiveAngle,profile,description...) OPCODE_SERVOTURNOUT,V(id),OPCODE_PAD,V(pin),OPCODE_PAD,V(activeAngle),OPCODE_PAD,V(inactiveAngle),OPCODE_PAD,V(PCA9685::ProfileType::profile),
 #define SET(pin) OPCODE_SET,V(pin),
 #define SET_TRACK(track,mode)  OPCODE_SET_TRACK,V(TRACK_MODE_##mode  <<8 | TRACK_NUMBER_##track),
 #define SET_POWER(track,onoff) OPCODE_SET_POWER,V(TRACK_POWER_##onoff),OPCODE_PAD, V(TRACK_NUMBER_##track),
 #define SETLOCO(loco) OPCODE_SETLOCO,V(loco),
 #define SIGNAL(redpin,amberpin,greenpin) 
 #define SIGNALH(redpin,amberpin,greenpin) 
@ -360,12 +461,20 @@ const  HIGHFLASH  int16_t RMFT2::SignalDefinitions[] = {
 #define START(route) OPCODE_START,V(route), 
 #define STOP OPCODE_SPEED,V(0), 
 #define THROW(id)  OPCODE_THROW,V(id),
 #ifndef IO_NO_HAL
 #define TT_ADDPOSITION(id,position,value,angle,description...) OPCODE_TTADDPOSITION,V(id),OPCODE_PAD,V(position),OPCODE_PAD,V(value),OPCODE_PAD,V(angle),
 #endif
 #define TURNOUT(id,addr,subaddr,description...) OPCODE_TURNOUT,V(id),OPCODE_PAD,V(addr),OPCODE_PAD,V(subaddr),
 #define TURNOUTL(id,addr,description...) TURNOUT(id,(addr-1)/4+1,(addr-1)%4, description)
 #define UNJOIN OPCODE_UNJOIN,0,0,
 #define UNLATCH(sensor_id) OPCODE_UNLATCH,V(sensor_id),
 #define VIRTUAL_SIGNAL(id) 
 #define VIRTUAL_TURNOUT(id,description...) OPCODE_PINTURNOUT,V(id),OPCODE_PAD,V(0), 
 #define WITHROTTLE(msg) PRINT(msg)
 #define WAITFOR(pin) OPCODE_WAITFOR,V(pin),
 #ifndef IO_NO_HAL
 #define WAITFORTT(turntable_id) OPCODE_WAITFORTT,V(turntable_id),
 #endif
 #define XFOFF(cab,func) OPCODE_XFOFF,V(cab),OPCODE_PAD,V(func),
 #define XFON(cab,func) OPCODE_XFON,V(cab),OPCODE_PAD,V(func),
--- a/GITHUB_SHA.h
+++ b/GITHUB_SHA.h
@ -1 +1 @@
-#define GITHUB_SHA "devel-202303252126Z"
+#define GITHUB_SHA "devel-202309241855Z"
--- a/I2CManager.cpp
+++ b/I2CManager.cpp
@ -92,7 +92,7 @@ void I2CManagerClass::begin(void) {
    // Probe and list devices.  Use standard mode 
    //  (clock speed 100kHz) for best device compatibility.
    _setClock(100000);
-    unsigned long originalTimeout = _timeout;
+    uint32_t originalTimeout = _timeout;
    setTimeout(1000);       // use 1ms timeout for probes
  #if defined(I2C_EXTENDED_ADDRESS)
--- a/I2CManager.h
+++ b/I2CManager.h
@ -485,7 +485,7 @@ private:
  // When retries are enabled, the timeout applies to each
  // try, and failure from timeout does not get retried.
  // A value of 0 means disable timeout monitoring.
-  unsigned long _timeout = 100000UL;
+  uint32_t _timeout = 100000UL;
  // Finish off request block by waiting for completion and posting status.
  uint8_t finishRB(I2CRB *rb, uint8_t status);
@ -532,13 +532,14 @@ private:
    uint8_t bytesToSend = 0;
    uint8_t bytesToReceive = 0;
    uint8_t operation = 0;
-    unsigned long startTime = 0;
+    uint32_t startTime = 0;
    uint8_t muxPhase = 0;
    uint8_t muxAddress = 0;
    uint8_t muxData[1];
    uint8_t deviceAddress;
    const uint8_t *sendBuffer;
    uint8_t *receiveBuffer;
    uint8_t transactionState = 0;
    volatile uint32_t pendingClockSpeed = 0;
--- a/I2CManager_NonBlocking.h
+++ b/I2CManager_NonBlocking.h
@ -172,6 +172,10 @@ void I2CManagerClass::startTransaction() {
 *  Function to queue a request block and initiate operations.
 ***************************************************************************/
 void I2CManagerClass::queueRequest(I2CRB *req) {
  if (((req->operation & OPERATION_MASK) == OPERATION_READ) && req->readLen == 0)
    return;  // Ignore null read
  req->status = I2C_STATUS_PENDING;
  req->nextRequest = NULL;
  ATOMIC_BLOCK() {
@ -184,6 +188,7 @@ void I2CManagerClass::queueRequest(I2CRB *req) {
 }
 /***************************************************************************
 *  Initiate a write to an I2C device (non-blocking operation)
 ***************************************************************************/
@ -240,8 +245,8 @@ void I2CManagerClass::checkForTimeout() {
    I2CRB *t = queueHead;
    if (state==I2C_STATE_ACTIVE && t!=0 && t==currentRequest && _timeout > 0) {
      // Check for timeout
-      unsigned long elapsed = micros() - startTime;
+      int32_t elapsed = micros() - startTime;
-      if (elapsed > _timeout) { 
+      if (elapsed > (int32_t)_timeout) { 
 #ifdef DIAG_IO
        //DIAG(F("I2CManager Timeout on %s"), t->i2cAddress.toString());
 #endif
@ -300,12 +305,12 @@ void I2CManagerClass::handleInterrupt() {
  // Check if current request has completed.  If there's a current request
  // and state isn't active then state contains the completion status of the request.
-  if (state == I2C_STATE_COMPLETED && currentRequest != NULL) {
+  if (state == I2C_STATE_COMPLETED && currentRequest != NULL && currentRequest == queueHead) {
    // Operation has completed.
    if (completionStatus == I2C_STATUS_OK || ++retryCounter > MAX_I2C_RETRIES
      || currentRequest->operation & OPERATION_NORETRY) 
    {
-      // Status is OK, or has failed and retry count exceeded, or retries disabled.
+      // Status is OK, or has failed and retry count exceeded, or failed and retries disabled.
 #if defined(I2C_EXTENDED_ADDRESS)
      if (muxPhase == MuxPhase_PROLOG ) {
        overallStatus = completionStatus;
--- a/I2CManager_STM32.h
+++ b/I2CManager_STM32.h
@ -26,27 +26,44 @@
 #include "I2CManager.h"
 #include "I2CManager_NonBlocking.h"   // to satisfy intellisense
 //#include <avr/io.h>
 //#include <avr/interrupt.h>
 #include <wiring_private.h>
 #include "stm32f4xx_hal_rcc.h"
-/***************************************************************************
+/*****************************************************************************
- *  Interrupt handler.
+ *  STM32F4xx I2C native driver support
- *  IRQ handler for SERCOM3 which is the default I2C definition for Arduino Zero
+ * 
- *  compatible variants such as the Sparkfun SAMD21 Dev Breakout etc.
+ *  Nucleo-64 and Nucleo-144 boards all use I2C1 as the default I2C peripheral
- *  Later we may wish to allow use of an alternate I2C bus, or more than one I2C
+ *  Later we may wish to support other STM32 boards, allow use of an alternate
- *  bus on the SAMD architecture 
+ *  I2C bus, or more than one I2C bus on the STM32 architecture 
- ***************************************************************************/
+ *****************************************************************************/
 #if defined(I2C_USE_INTERRUPTS) && defined(ARDUINO_ARCH_STM32)
-void I2C1_IRQHandler() {
+#if defined(ARDUINO_NUCLEO_F401RE) || defined(ARDUINO_NUCLEO_F411RE) || defined(ARDUINO_NUCLEO_F446RE) \
    || defined(ARDUINO_NUCLEO_F412ZG) || defined(ARDUINO_NUCLEO_F413ZH) \
    || defined(ARDUINO_NUCLEO_F429ZI) || defined(ARDUINO_NUCLEO_F446ZE)
 // Assume I2C1 for now - default I2C bus on Nucleo-F411RE and likely all Nucleo-64
 // and Nucleo-144 variants
 I2C_TypeDef *s = I2C1;
 // In init we will ask the STM32 HAL layer for the configured APB1 clock frequency in Hz
 uint32_t APB1clk1; // Peripheral Input Clock speed in Hz.
 uint32_t i2c_MHz;  // Peripheral Input Clock speed in MHz.
 // IRQ handler for I2C1, replacing the weak definition in the STM32 HAL 
 extern "C" void I2C1_EV_IRQHandler(void) {
  I2CManager.handleInterrupt();
 }
 extern "C" void I2C1_ER_IRQHandler(void) {
  I2CManager.handleInterrupt();
 }
 #else
 #warning STM32 board selected is not yet supported - so I2C1 peripheral is not defined
 #endif
 #endif
-// Assume I2C1 for now - default I2C bus on Nucleo-F411RE and likely Nucleo-64 variants
+// Peripheral Input Clock speed in MHz.
-I2C_TypeDef *s = I2C1;
+// For STM32F446RE, the speed is 45MHz.  Ideally, this should be determined
-#define I2C_IRQn  I2C1_EV_IRQn
+// at run-time from the APB1 clock, as it can vary from STM32 family to family.
-#define I2C_BUSFREQ 16
+// #define I2C_PERIPH_CLK 45
 // I2C SR1 Status Register #1 bit definitions for convenience
 // #define I2C_SR1_SMBALERT  (1<<15)   // SMBus alert
@ -80,52 +97,66 @@ I2C_TypeDef *s = I2C1;
 // #define I2C_CR1_SMBUS     (1<<1)    // SMBus mode, 1=SMBus, 0=I2C
 // #define I2C_CR1_PE        (1<<0)    // I2C Peripheral enable
 // States of the STM32 I2C driver state machine
 enum {TS_IDLE,TS_START,TS_W_ADDR,TS_W_DATA,TS_W_STOP,TS_R_ADDR,TS_R_DATA,TS_R_STOP};
 /***************************************************************************
 *  Set I2C clock speed register.  This should only be called outside of
 *  a transmission.  The I2CManagerClass::_setClock() function ensures 
 *  that it is only called at the beginning of an I2C transaction.
 ***************************************************************************/
 void I2CManagerClass::I2C_setClock(uint32_t i2cClockSpeed) {
  // Calculate a rise time appropriate to the requested bus speed
-  // Use 10x the rise time spec to enable integer divide of 62.5ns clock period
+  // Use 10x the rise time spec to enable integer divide of 50ns clock period
  uint16_t t_rise;
  uint32_t ccr_freq;
-  if (i2cClockSpeed < 200000L) {
+
-    // i2cClockSpeed = 100000L;
+  while (s->CR1 & I2C_CR1_STOP);  // Prevents lockup by guarding further
-    t_rise = 0x11;  // (1000ns /62.5ns) + 1;
+                                  // writes to CR1 while STOP is being executed!
-  }
+
-  else if (i2cClockSpeed < 800000L)
+  // Disable the I2C device, as TRISE can only be programmed whilst disabled
  s->CR1 &= ~(I2C_CR1_PE);  // Disable I2C
  s->CR1 |= I2C_CR1_SWRST;  // reset the I2C
  asm("nop");    // wait a bit... suggestion from online!
  s->CR1 &= ~(I2C_CR1_SWRST); // Normal operation
  if (i2cClockSpeed > 100000UL)
  {
-    i2cClockSpeed = 400000L;
+    // if (i2cClockSpeed > 400000L)
-    t_rise = 0x06;  // (300ns / 62.5ns) + 1;
+    //   i2cClockSpeed = 400000L;
-    // } else if (i2cClockSpeed < 1200000L) {
+
-    //   i2cClockSpeed = 1000000L;
+    t_rise = 300;  // nanoseconds
    //   t_rise = 120;
  }
  else
  {
-    i2cClockSpeed = 100000L;
+    // i2cClockSpeed = 100000L;
-    t_rise = 0x11;  // (1000ns /62.5ns) + 1;
+    t_rise = 1000;  // nanoseconds
  }
-
+  // Configure the rise time register - max allowed tRISE is 1000ns,
-  // Enable the I2C master mode
+  // so value = 1000ns * I2C_PERIPH_CLK MHz / 1000 + 1.
-  s->CR1 &= ~(I2C_CR1_PE);  // Enable I2C
+  s->TRISE = (t_rise * i2c_MHz / 1000) + 1;
  // Software reset the I2C peripheral
  // s->CR1 |= I2C_CR1_SWRST;  // reset the I2C
  // Release reset
  // s->CR1 &= ~(I2C_CR1_SWRST);  // Normal operation
  // Calculate baudrate - using a rise time appropriate for the speed
  ccr_freq = I2C_BUSFREQ * 1000000 / i2cClockSpeed / 2;
  // Bit 15: I2C Master mode, 0=standard, 1=Fast Mode
-  // Bit 14: Duty, fast mode duty cycle
+  // Bit 14: Duty, fast mode duty cycle (use 2:1)
-  // Bit 11-0: FREQR = 16MHz => TPCLK1 = 62.5ns, so CCR divisor must be 0x50 (80 * 62.5ns = 5000ns)
+  // Bit 11-0: FREQR
-  s->CCR = (uint16_t)ccr_freq;
+  // if (i2cClockSpeed > 400000UL) {
  //   // In fast mode plus, I2C period is 3 * CCR * TPCLK1.
  //   // s->CCR &= ~(0x3000); // Clear all bits except 12 and 13 which must remain per reset value
  //   s->CCR = APB1clk1 / 3 / i2cClockSpeed; // Set I2C clockspeed to start!
  //   s->CCR |= 0xC000; // We need Fast Mode AND DUTY bits set
  // } else {
    // In standard and fast mode, I2C period is 2 * CCR * TPCLK1
    s->CCR &= ~(0x3000); // Clear all bits except 12 and 13 which must remain per reset value
    s->CCR |= (APB1clk1 / 2 / i2cClockSpeed); // Set I2C clockspeed to start!
    // s->CCR |= (i2c_MHz * 500 / (i2cClockSpeed / 1000)); // Set I2C clockspeed to start!
    // if (i2cClockSpeed > 100000UL)
    //     s->CCR |= 0xC000; // We need Fast Mode bits set as well
  // }
-  // Configure the rise time register
+  // DIAG(F("I2C_init() peripheral clock is now: %d, full reg is %x"), (s->CR2 & 0xFF), s->CR2);
-  s->TRISE = t_rise;  // 1000 ns / 62.5 ns = 16 + 1
+  // DIAG(F("I2C_init() peripheral CCR is now: %d"), s->CCR);
  // DIAG(F("I2C_init() peripheral TRISE is now: %d"), s->TRISE);
  // Enable the I2C master mode
  s->CR1 |= I2C_CR1_PE;  // Enable I2C
@ -136,32 +167,54 @@ void I2CManagerClass::I2C_setClock(uint32_t i2cClockSpeed) {
 ***************************************************************************/
 void I2CManagerClass::I2C_init()
 {
-  //Setting up the clocks
+  // Query the clockspeed from the STM32 HAL layer
-  RCC->APB1ENR |= (1<<21);  // Enable I2C CLOCK
+  APB1clk1 = HAL_RCC_GetPCLK1Freq();
-  RCC->AHB1ENR |= (1<<1);   // Enable GPIOB CLOCK for PB8/PB9
+  i2c_MHz = APB1clk1 / 1000000UL;
  // DIAG(F("I2C_init() peripheral clock speed is: %d"), i2c_MHz);
  // Enable clocks
  RCC->APB1ENR |= RCC_APB1ENR_I2C1EN;//(1 << 21); // Enable I2C CLOCK
  // Reset the I2C1 peripheral to initial state
  RCC->APB1RSTR |=  RCC_APB1RSTR_I2C1RST;
 	RCC->APB1RSTR &= ~RCC_APB1RSTR_I2C1RST;
  // Standard I2C pins are SCL on PB8 and SDA on PB9
  RCC->AHB1ENR |= (1<<1);   // Enable GPIOB CLOCK for PB8/PB9
  // Bits (17:16)= 1:0 --> Alternate Function for Pin PB8;
  // Bits (19:18)= 1:0 --> Alternate Function for Pin PB9
  GPIOB->MODER &= ~((3<<(8*2)) | (3<<(9*2)));    // Clear all MODER bits for PB8 and PB9
  GPIOB->MODER |= (2<<(8*2)) | (2<<(9*2));    // PB8 and PB9 set to ALT function
  GPIOB->OTYPER |= (1<<8) | (1<<9);           // PB8 and PB9 set to open drain output capability
  GPIOB->OSPEEDR |= (3<<(8*2)) | (3<<(9*2));  // PB8 and PB9 set to High Speed mode
  GPIOB->PUPDR &= ~((3<<(8*2)) | (3<<(9*2))); // Clear all PUPDR bits for PB8 and PB9
  GPIOB->PUPDR |= (1<<(8*2)) | (1<<(9*2));    // PB8 and PB9 set to pull-up capability
  // Alt Function High register routing pins PB8 and PB9 for I2C1:
  // Bits (3:2:1:0) = 0:1:0:0 --> AF4 for pin PB8
  // Bits (7:6:5:4) = 0:1:0:0 --> AF4 for pin PB9
  GPIOB->AFR[1] &= ~((15<<0) | (15<<4));      // Clear all AFR bits for PB8 on low nibble, PB9 on next nibble up
  GPIOB->AFR[1] |= (4<<0) | (4<<4);           // PB8 on low nibble, PB9 on next nibble up
  // Software reset the I2C peripheral
  I2C1->CR1 &= ~I2C_CR1_PE; // Disable I2C1 peripheral
  s->CR1 |= I2C_CR1_SWRST;  // reset the I2C
-  s->CR1 &= ~(I2C_CR1_SWRST);  // Normal operation
+  asm("nop");    // wait a bit... suggestion from online!
  s->CR1 &= ~(I2C_CR1_SWRST); // Normal operation
-  // Program the peripheral input clock in CR2 Register in order to generate correct timings
+  // Clear all bits in I2C CR2 register except reserved bits
-  s->CR2 |= I2C_BUSFREQ;  // PCLK1 FREQUENCY in MHz
+  s->CR2 &= 0xE000;
  // Set I2C peripheral clock frequency
  // s->CR2 |= I2C_PERIPH_CLK;
  s->CR2 |= i2c_MHz;
  // DIAG(F("I2C_init() peripheral clock is now: %d"), s->CR2);
  // set own address to 00 - not used in master mode
  I2C1->OAR1 = (1 << 14); // bit 14 should be kept at 1 according to the datasheet
 #if defined(I2C_USE_INTERRUPTS)
  // Setting NVIC
-  NVIC_SetPriority(I2C_IRQn, 1);  // Match default priorities
+  NVIC_SetPriority(I2C1_EV_IRQn, 1);  // Match default priorities
-  NVIC_EnableIRQ(I2C_IRQn);
+  NVIC_EnableIRQ(I2C1_EV_IRQn);
  NVIC_SetPriority(I2C1_ER_IRQn, 1);  // Match default priorities
  NVIC_EnableIRQ(I2C1_ER_IRQn);
  // CR2 Interrupt Settings
  // Bit 15-13: reserved
@ -172,23 +225,28 @@ void I2CManagerClass::I2C_init()
  // Bit 8: ITERREN - Error interrupt enable
  // Bit 7-6: reserved
  // Bit 5-0: FREQ - Peripheral clock frequency (max 50MHz)
-  // s->CR2 |= 0x0700;   // Enable Buffer, Event and Error interrupts
+  s->CR2 |= (I2C_CR2_ITBUFEN | I2C_CR2_ITEVTEN | I2C_CR2_ITERREN);   // Enable Buffer, Event and Error interrupts
  s->CR2 |= 0x0300;   // Enable Event and Error interrupts
 #endif
  // DIAG(F("I2C_init() setting initial I2C clock to 100KHz"));
  // Calculate baudrate and set default rate for now
  // Configure the Clock Control Register for 100KHz SCL frequency
  // Bit 15: I2C Master mode, 0=standard, 1=Fast Mode
  // Bit 14: Duty, fast mode duty cycle
-  // Bit 11-0: FREQR = 16MHz => TPCLK1 = 62.5ns, so CCR divisor must be 0x50 (80 * 62.5ns = 5000ns)
+  // Bit 11-0: so CCR divisor would be clk / 2 / 100000 (where clk is in Hz)
-  s->CCR = 0x0050;
+  // s->CCR = I2C_PERIPH_CLK * 5;
  s->CCR &= ~(0x3000); // Clear all bits except 12 and 13 which must remain per reset value
  s->CCR |= (APB1clk1 / 2 / 100000UL); // Set a default of 100KHz I2C clockspeed to start!
-  // Configure the rise time register - max allowed in 1000ns
+  // Configure the rise time register - max allowed is 1000ns, so value = 1000ns * I2C_PERIPH_CLK MHz / 1000 + 1.
-  s->TRISE = 0x0011; // 1000 ns / 62.5 ns = 16 + 1
+  s->TRISE = (1000 * i2c_MHz / 1000) + 1;
  // DIAG(F("I2C_init() peripheral clock is now: %d, full reg is %x"), (s->CR2 & 0xFF), s->CR2);
  // DIAG(F("I2C_init() peripheral CCR is now: %d"), s->CCR);
  // DIAG(F("I2C_init() peripheral TRISE is now: %d"), s->TRISE);
  // Enable the I2C master mode
  s->CR1 |= I2C_CR1_PE;  // Enable I2C
  // Setting bus idle mode and wait for sync
 }
 /***************************************************************************
@ -198,49 +256,30 @@ void I2CManagerClass::I2C_sendStart() {
  // Set counters here in case this is a retry.
  rxCount = txCount = 0;
  uint8_t temp;
  // On a single-master I2C bus, the start bit won't be sent until the bus
  // state goes to IDLE so we can request it without waiting.  On a
  // multi-master bus, the bus may be BUSY under control of another master,
  // in which case we can avoid some arbitration failures by waiting until
  // the bus state is IDLE.  We don't do that here.
  //while (s->SR2 & I2C_SR2_BUSY) {}
-  // If anything to send, initiate write.  Otherwise initiate read.
+  // Check there's no STOP still in progress.  If we OR the START bit into CR1
-  if (operation == OPERATION_READ || ((operation == OPERATION_REQUEST) && !bytesToSend))
+  // and the STOP bit is already set, we could output multiple STOP conditions.
-  {
+  while (s->CR1 & I2C_CR1_STOP) {}  // Wait for STOP bit to reset
-    // Send start for read operation
+
-    s->CR1 |= I2C_CR1_ACK;  // Enable the ACK
+  s->CR2 |= (I2C_CR2_ITEVTEN | I2C_CR2_ITERREN);  // Enable interrupts
-    s->CR1 |= I2C_CR1_START;  // Generate START
+  s->CR2 &= ~I2C_CR2_ITBUFEN;     // Don't enable buffer interupts yet.
-    // Send address with read flag (1) or'd in
+  s->CR1 &= ~I2C_CR1_POS;   // Clear the POS bit
-    s->DR = (deviceAddress << 1) | 1;  //  send the address
+  s->CR1 |= (I2C_CR1_ACK | I2C_CR1_START);   // Enable the ACK and generate START
-    while (!(s->SR1 && I2C_SR1_ADDR));  // wait for ADDR bit to set
+  transactionState = TS_START;
    // Special case for 1 byte reads!
    if (bytesToReceive == 1)
    {
      s->CR1 &= ~I2C_CR1_ACK;            // clear the ACK bit 
 		  temp = I2C1->SR1 | I2C1->SR2;  // read SR1 and SR2 to clear the ADDR bit.... EV6 condition
 		  s->CR1 |= I2C_CR1_STOP;              // Stop I2C
    }
    else
      temp = s->SR1 | s->SR2;        // read SR1 and SR2 to clear the ADDR bit
  }
  else {
    // Send start for write operation
    s->CR1 |= I2C_CR1_ACK;  // Enable the ACK
    s->CR1 |= I2C_CR1_START;  // Generate START
    // Send address with write flag (0) or'd in
    s->DR = (deviceAddress << 1) | 0;  //  send the address
    while (!(s->SR1 && I2C_SR1_ADDR));  // wait for ADDR bit to set
    temp = s->SR1 | s->SR2;  // read SR1 and SR2 to clear the ADDR bit
  }
 }
 /***************************************************************************
 *  Initiate a stop bit for transmission (does not interrupt)
 ***************************************************************************/
 void I2CManagerClass::I2C_sendStop() {
-  s->CR1 |= I2C_CR1_STOP;              // Stop I2C
+  s->CR1 |= I2C_CR1_STOP; // Stop I2C
 }
 /***************************************************************************
@ -252,9 +291,11 @@ void I2CManagerClass::I2C_close() {
  s->CR1 &= ~I2C_CR1_PE;  // Disable I2C peripheral
  // Should never happen, but wait for up to 500us only.
  unsigned long startTime = micros();
-  while ((s->CR1 && I2C_CR1_PE) != 0) {
+  while ((s->CR1 & I2C_CR1_PE) != 0) {
-    if (micros() - startTime >= 500UL) break;
+    if ((int32_t)(micros() - startTime) >= 500) break;
  }
  NVIC_DisableIRQ(I2C1_EV_IRQn);
  NVIC_DisableIRQ(I2C1_ER_IRQn);
 }
 /***************************************************************************
@ -263,50 +304,217 @@ void I2CManagerClass::I2C_close() {
 *  (and therefore, indirectly, from I2CRB::wait() and I2CRB::isBusy()).
 ***************************************************************************/
 void I2CManagerClass::I2C_handleInterrupt() {
  volatile uint16_t temp_sr1, temp_sr2;
-  if (s->SR1 && I2C_SR1_ARLO) {
+  temp_sr1 = s->SR1;
-    // Arbitration lost, restart
+
-    I2C_sendStart();   // Reinitiate request
+  // Check for errors first
-  } else if (s->SR1 && I2C_SR1_BERR) {
+  if (temp_sr1 & (I2C_SR1_AF | I2C_SR1_ARLO | I2C_SR1_BERR)) {
-    // Bus error
+    // Check which error flag is set
-    completionStatus = I2C_STATUS_BUS_ERROR;
+    if (temp_sr1 & I2C_SR1_AF)
-    state = I2C_STATE_COMPLETED;
+    {
-  } else if (s->SR1 && I2C_SR1_TXE) {
+      s->SR1 &= ~(I2C_SR1_AF); // Clear AF
-    // Master write completed
+      I2C_sendStop(); // Clear the bus
-    if (s->SR1 && (1<<10)) {
+      transactionState = TS_IDLE;
      // Nacked, send stop.
      I2C_sendStop();
      completionStatus = I2C_STATUS_NEGATIVE_ACKNOWLEDGE;
      state = I2C_STATE_COMPLETED;
    } else if (bytesToSend) {
      // Acked, so send next byte
      s->DR = sendBuffer[txCount++];
      bytesToSend--;
    } else if (bytesToReceive) {
      // Last sent byte acked and no more to send.  Send repeated start, address and read bit.
      // s->I2CM.ADDR.bit.ADDR = (deviceAddress << 1) | 1;
    } else {
      // Check both TxE/BTF == 1 before generating stop
      while (!(s->SR1 && I2C_SR1_TXE));    // Check TxE
      while (!(s->SR1 && I2C_SR1_BTF));    // Check BTF
      // No more data to send/receive. Initiate a STOP condition and finish
      I2C_sendStop();
      state = I2C_STATE_COMPLETED;
    }
-  } else if (s->SR1 && I2C_SR1_RXNE) {
+    else if (temp_sr1 & I2C_SR1_ARLO)
-    // Master read completed without errors
+    {
-    if (bytesToReceive == 1) {
+      // Arbitration lost, restart
-//      s->I2CM.CTRLB.bit.ACKACT = 1;  // NAK final byte
+      s->SR1 &= ~(I2C_SR1_ARLO); // Clear ARLO
-      I2C_sendStop();  // send stop
+      I2C_sendStart(); // Reinitiate request
-      receiveBuffer[rxCount++] = s->DR;  // Store received byte
+      transactionState = TS_START;
-      bytesToReceive = 0;
+    }
    else if (temp_sr1 & I2C_SR1_BERR)
    {
      // Bus error
      s->SR1 &= ~(I2C_SR1_BERR); // Clear BERR
      I2C_sendStop(); // Clear the bus
      transactionState = TS_IDLE;
      completionStatus = I2C_STATUS_BUS_ERROR;
      state = I2C_STATE_COMPLETED;
    } else if (bytesToReceive) {
 //      s->I2CM.CTRLB.bit.ACKACT = 0;  // ACK all but final byte
      receiveBuffer[rxCount++] = s->DR;  // Store received byte
      bytesToReceive--;
    }
  } 
  else {
    // No error flags, so process event according to current state.
    switch (transactionState) {
      case TS_START:
        if (temp_sr1 & I2C_SR1_SB) {
          // Event EV5
          // Start bit has been sent successfully and we have the bus.
          // If anything to send, initiate write.  Otherwise initiate read.
          if (operation == OPERATION_READ || ((operation == OPERATION_REQUEST) && !bytesToSend)) {
            // Send address with read flag (1) or'd in
            s->DR = (deviceAddress << 1) | 1;  //  send the address
            transactionState = TS_R_ADDR;
          } else {
            // Send address with write flag (0) or'd in
            s->DR = (deviceAddress << 1) | 0;  //  send the address
            transactionState = TS_W_ADDR;
          }
        }
        // SB bit is cleared by writing to DR (already done).
        break;
      case TS_W_ADDR:
        if (temp_sr1 & I2C_SR1_ADDR) {
          temp_sr2 = s->SR2; // read SR2 to complete clearing the ADDR bit
          // Event EV6
          // Address sent successfully, device has ack'd in response.
          if (!bytesToSend) {
            I2C_sendStop();
            transactionState = TS_IDLE;
            completionStatus = I2C_STATUS_OK;
            state = I2C_STATE_COMPLETED;
          } else {
            // Put one byte into DR to load shift register.
            s->DR = sendBuffer[txCount++];
            bytesToSend--;
            if (bytesToSend) {
              // Put another byte to load DR
              s->DR = sendBuffer[txCount++];
              bytesToSend--;
            }
            if (!bytesToSend) {
              // No more bytes to send.
              // The TXE interrupt occurs when the DR is empty, and the BTF interrupt 
              // occurs when the shift register is also empty (one character later).
              // To avoid repeated TXE interrupts during this time, we disable TXE interrupt.
              s->CR2 &= ~I2C_CR2_ITBUFEN;  // Wait for BTF interrupt, disable TXE interrupt
              transactionState = TS_W_STOP;
            } else {
              // More data remaining to send after this interrupt, enable TXE interrupt.
              s->CR2 |= I2C_CR2_ITBUFEN;
              transactionState = TS_W_DATA;
            }
          }
        }
        break;
      case TS_W_DATA:
        if (temp_sr1 & I2C_SR1_TXE) {
          // Event EV8_1/EV8
          // Transmitter empty, write a byte to it.
          if (bytesToSend) {
            s->DR = sendBuffer[txCount++];
            bytesToSend--;
            if (!bytesToSend) {
              s->CR2 &= ~I2C_CR2_ITBUFEN;  // Disable TXE interrupt
              transactionState = TS_W_STOP;
            }
          }
        } 
        break;
      case TS_W_STOP:
        if (temp_sr1 & I2C_SR1_BTF) {
          // Event EV8_2
          // Done, last character sent. Anything to receive?
          if (bytesToReceive) {
            I2C_sendStart();
            // NOTE: Three redundant BTF interrupts take place between the
            // first BTF interrupt and the START interrupt.  I've tried all sorts
            // of ways to eliminate them, and the only thing that worked for
            // me was to loop until the BTF bit becomes reset.  Either way,
            // it's a waste of processor time.  Anyone got a solution?
            //while (s->SR1 && I2C_SR1_BTF) {}
            transactionState = TS_START;
          } else {
            I2C_sendStop();
            transactionState = TS_IDLE;
            completionStatus = I2C_STATUS_OK;
            state = I2C_STATE_COMPLETED;
          }
          s->SR1 &= I2C_SR1_BTF;  // Clear BTF interrupt
        }
        break;
      case TS_R_ADDR:
        if (temp_sr1 & I2C_SR1_ADDR) {
          // Event EV6
          // Address sent for receive.
          // The next bit is different depending on whether there are 
          // 1 byte, 2 bytes or >2 bytes to be received, in accordance with the
          // Programmers Reference RM0390.
          if (bytesToReceive == 1) {
            // Receive 1 byte
            s->CR1 &= ~I2C_CR1_ACK;  // Disable ack
            temp_sr2 = s->SR2; // read SR2 to complete clearing the ADDR bit
            // Next step will occur after a RXNE interrupt, so enable it
            s->CR2 |= I2C_CR2_ITBUFEN;
            transactionState = TS_R_STOP;
          } else if (bytesToReceive == 2) {
            // Receive 2 bytes
            s->CR1 &= ~I2C_CR1_ACK;  // Disable ACK for final byte
            s->CR1 |= I2C_CR1_POS;  // set POS flag to delay effect of ACK flag
            // Next step will occur after a BTF interrupt, so disable RXNE interrupt
            s->CR2 &= ~I2C_CR2_ITBUFEN;
            temp_sr2 = s->SR2; // read SR2 to complete clearing the ADDR bit
            transactionState = TS_R_STOP;
          } else {
            // >2 bytes, just wait for bytes to come in and ack them for the time being
            // (ack flag has already been set).
            // Next step will occur after a BTF interrupt, so disable RXNE interrupt
            s->CR2 &= ~I2C_CR2_ITBUFEN;
            temp_sr2 = s->SR2; // read SR2 to complete clearing the ADDR bit
            transactionState = TS_R_DATA;
          }
        }
        break;
      case TS_R_DATA:
        // Event EV7/EV7_1
        if (temp_sr1 & I2C_SR1_BTF) {
          // Byte received in receiver - read next byte
          if (bytesToReceive == 3) {
            // Getting close to the last byte, so a specific sequence is recommended.
            s->CR1 &= ~I2C_CR1_ACK;  // Reset ack for next byte received.
            transactionState = TS_R_STOP;
          }
          receiveBuffer[rxCount++] = s->DR;  // Store received byte
          bytesToReceive--;
        } 
        break;
      case TS_R_STOP:
        if (temp_sr1 & I2C_SR1_BTF) {
          // Event EV7 (last one)
          // When we've got here, the receiver has got the last two bytes
          // (or one byte, if only one byte is being received),
          // and NAK has already been sent, so we need to read from the receiver.
          if (bytesToReceive) {
            if (bytesToReceive > 1) 
              I2C_sendStop();
            while(bytesToReceive) {
              receiveBuffer[rxCount++] = s->DR;  // Store received byte(s)
              bytesToReceive--;
            }
            // Finish.
            transactionState = TS_IDLE;
            completionStatus = I2C_STATUS_OK;
            state = I2C_STATE_COMPLETED;
          }
        } else if (temp_sr1 & I2C_SR1_RXNE) {
          if (bytesToReceive == 1) {
            // One byte on a single-byte transfer.  Ack has already been set.
            I2C_sendStop();
            receiveBuffer[rxCount++] = s->DR; // Store received byte
            bytesToReceive--;
            // Finish.
            transactionState = TS_IDLE;
            completionStatus = I2C_STATUS_OK;
            state = I2C_STATE_COMPLETED;
          } else
            s->SR1 &= I2C_SR1_RXNE;  // Acknowledge interrupt
        }
        break;
    }
    // If we've received an interrupt at any other time, we're not interested so clear it
    // to prevent it recurring ad infinitum.
    s->SR1 = 0;
  }
 }
 #endif /* I2CMANAGER_STM32_H */
--- a/IODevice.cpp
+++ b/IODevice.cpp
@ -176,6 +176,13 @@ bool IODevice::exists(VPIN vpin) {
  return findDevice(vpin) != NULL;
 }
 // Return the status of the device att vpin.
 uint8_t IODevice::getStatus(VPIN vpin) {
  IODevice *dev = findDevice(vpin);
  if (!dev) return false;
  return dev->_deviceState;
 }
 // check whether the pin supports notification.  If so, then regular _read calls are not required.
 bool IODevice::hasCallback(VPIN vpin) {
  IODevice *dev = findDevice(vpin);
--- a/IODevice.h
+++ b/IODevice.h
@ -27,12 +27,6 @@
 // Define symbol DIAG_LOOPTIMES to enable CS loop execution time to be reported
 //#define DIAG_LOOPTIMES
 // Define symbol IO_NO_HAL to reduce FLASH footprint when HAL features not required
 // The HAL is disabled by default on Nano and Uno platforms, because of limited flash space.
 #if defined(ARDUINO_AVR_NANO) || defined(ARDUINO_AVR_UNO) 
 #define IO_NO_HAL
 #endif
 // Define symbol IO_SWITCH_OFF_SERVO to set the PCA9685 output to 0 when an 
 // animation has completed.  This switches off the servo motor, preventing 
 // the continuous buzz sometimes found on servos, and reducing the 
@ -160,6 +154,9 @@ public:
  // exists checks whether there is a device owning the specified vpin
  static bool exists(VPIN vpin);
  // getStatus returns the state of the device at the specified vpin
  static uint8_t getStatus(VPIN vpin);
  // Enable shared interrupt on specified pin for GPIO extender modules.  The extender module
  // should pull down this pin when requesting a scan.  The pin may be shared by multiple modules.
  // Without the shared interrupt, input states are scanned periodically to detect changes on 
@ -383,6 +380,7 @@ private:
  uint8_t *_pinInUse; 
 };
 #ifndef IO_NO_HAL
 /////////////////////////////////////////////////////////////////////////////////////////////////////
 /*
 * IODevice subclass for EX-Turntable.
@ -411,10 +409,14 @@ private:
  void _begin() override;
  void _loop(unsigned long currentMicros) override;
  int _read(VPIN vpin) override;
  void _broadcastStatus (VPIN vpin, uint8_t status, uint8_t activity);
  void _writeAnalogue(VPIN vpin, int value, uint8_t activity, uint16_t duration) override;
  void _display() override;
  uint8_t _stepperStatus;
  uint8_t _previousStatus;
  uint8_t _currentActivity;
 };
 #endif
 /////////////////////////////////////////////////////////////////////////////////////////////////////
--- a/IO_EXTurntable.cpp
+++ b/IO_EXTurntable.cpp
@ -20,20 +20,21 @@
 /*
 * The IO_EXTurntable device driver is used to control a turntable via an Arduino with a stepper motor over I2C.
 *
-* The EX-Turntable code lives in a separate repo (https://github.com/DCC-EX/Turntable-EX) and contains the stepper motor logic.
+* The EX-Turntable code lives in a separate repo (https://github.com/DCC-EX/EX-Turntable) and contains the stepper motor logic.
 *
-* This device driver sends a step position to Turntable-EX to indicate the step position to move to using either of these commands:
+* This device driver sends a step position to EX-Turntable to indicate the step position to move to using either of these commands:
 * <D TT vpin steps activity> in the serial console
 * MOVETT(vpin, steps, activity) in EX-RAIL
 * Refer to the documentation for further information including the valid activities.
 */
 #ifndef IO_EXTurntable_h
 #define IO_EXTurntable_h
 #include "IODevice.h"
 #include "I2CManager.h"
 #include "DIAG.h"
 #include "Turntables.h"
 #include "CommandDistributor.h"
 #ifndef IO_NO_HAL
 void EXTurntable::create(VPIN firstVpin, int nPins, I2CAddress I2CAddress) {
  new EXTurntable(firstVpin, nPins, I2CAddress);
@ -44,18 +45,21 @@ EXTurntable::EXTurntable(VPIN firstVpin, int nPins, I2CAddress I2CAddress) {
  _firstVpin = firstVpin;
  _nPins = nPins;
  _I2CAddress = I2CAddress;
  _stepperStatus = 0;
  _previousStatus = 0;
  addDevice(this);
 }
 // Initialisation of EXTurntable
 void EXTurntable::_begin() {
  I2CManager.begin();
  I2CManager.setClock(1000000);
  if (I2CManager.exists(_I2CAddress)) {
    DIAG(F("EX-Turntable device found, I2C:%s"), _I2CAddress.toString());
 #ifdef DIAG_IO
    _display();
 #endif
  } else {
    DIAG(F("EX-Turntable I2C:%s device not found"), _I2CAddress.toString());
    _deviceState = DEVSTATE_FAILED;
  }
 }
@ -67,15 +71,19 @@ void EXTurntable::_loop(unsigned long currentMicros) {
  uint8_t readBuffer[1];
  I2CManager.read(_I2CAddress, readBuffer, 1);
  _stepperStatus = readBuffer[0];
-  // DIAG(F("Turntable-EX returned status: %d"), _stepperStatus);
+  if (_stepperStatus != _previousStatus && _stepperStatus == 0) { // Broadcast when a rotation finishes
-  delayUntil(currentMicros + 500000);  // Wait 500ms before checking again, turntables turn slowly
+    if ( _currentActivity < 4) {
      _broadcastStatus(_firstVpin, _stepperStatus, _currentActivity);
    }
    _previousStatus = _stepperStatus;
  }
  delayUntil(currentMicros + 100000);  // Wait 100ms before checking again
 }
 // Read returns status as obtained in our loop.
 // Return false if our status value is invalid.
 int EXTurntable::_read(VPIN vpin) {
  if (_deviceState == DEVSTATE_FAILED) return 0;
  // DIAG(F("_read status: %d"), _stepperStatus);
  if (_stepperStatus > 1) {
    return false;
  } else {
@ -83,6 +91,17 @@ int EXTurntable::_read(VPIN vpin) {
  }
 }
 // If a status change has occurred for a turntable object, broadcast it
 void EXTurntable::_broadcastStatus (VPIN vpin, uint8_t status, uint8_t activity) {
  Turntable *tto = Turntable::getByVpin(vpin);
  if (tto) {
    if (activity < 4) {
      tto->setMoving(status);
      CommandDistributor::broadcastTurntable(tto->getId(), tto->getPosition(), status);
    }
  }
 }
 // writeAnalogue to send the steps and activity to Turntable-EX.
 // Sends 3 bytes containing the MSB and LSB of the step count, and activity.
 // value contains the steps, bit shifted to MSB + LSB.
@ -100,6 +119,7 @@ int EXTurntable::_read(VPIN vpin) {
 // Acc_Off = 9           // Turn accessory pin off
 void EXTurntable::_writeAnalogue(VPIN vpin, int value, uint8_t activity, uint16_t duration) {
  if (_deviceState == DEVSTATE_FAILED) return;
  if (value < 0) return;
  uint8_t stepsMSB = value >> 8;
  uint8_t stepsLSB = value & 0xFF;
 #ifdef DIAG_IO
@ -108,7 +128,10 @@ void EXTurntable::_writeAnalogue(VPIN vpin, int value, uint8_t activity, uint16_
  DIAG(F("I2CManager write I2C Address:%d stepsMSB:%d stepsLSB:%d activity:%d"),
    _I2CAddress.toString(), stepsMSB, stepsLSB, activity);
 #endif
-  _stepperStatus = 1;     // Tell the device driver Turntable-EX is busy
+  if (activity < 4) _stepperStatus = 1;     // Tell the device driver Turntable-EX is busy
  _previousStatus = _stepperStatus;
  _currentActivity = activity;
  _broadcastStatus(vpin, _stepperStatus, activity); // Broadcast when the rotation starts
  I2CManager.write(_I2CAddress, 3, stepsMSB, stepsLSB, activity);
 }
--- a/IO_PCA9555.h
+++ b/IO_PCA9555.h
@ -0,0 +1,111 @@
 /*
 *  © 2021, Neil McKechnie. All rights reserved.
 *  
 *  This file is part of DCC++EX API
 *
 *  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/>.
 */
 #ifndef io_pca9555_h
 #define io_pca9555_h
 #include "IO_GPIOBase.h"
 #include "FSH.h"
 /////////////////////////////////////////////////////////////////////////////////////////////////////
 /*
 * IODevice subclass for PCA9555 16-bit I/O expander (NXP & Texas Instruments).
 */
 class PCA9555 : public GPIOBase<uint16_t> {
 public:
  static void create(VPIN vpin, uint8_t nPins, I2CAddress i2cAddress, int interruptPin=-1) {
    if (checkNoOverlap(vpin, nPins, i2cAddress)) new PCA9555(vpin,nPins, i2cAddress, interruptPin);
  }
 private:  
  // Constructor
  PCA9555(VPIN vpin, uint8_t nPins, I2CAddress I2CAddress, int interruptPin=-1) 
    : GPIOBase<uint16_t>((FSH *)F("PCA9555"), vpin, nPins, I2CAddress, interruptPin) 
  {
    requestBlock.setRequestParams(_I2CAddress, inputBuffer, sizeof(inputBuffer),
      outputBuffer, sizeof(outputBuffer));
    outputBuffer[0] = REG_INPUT_P0;
  }
  void _writeGpioPort() override {
    I2CManager.write(_I2CAddress, 3, REG_OUTPUT_P0, _portOutputState, _portOutputState>>8);
  }
  void _writePullups() override {
    // Do nothing, pull-ups are always in place for input ports
    // This function is here for HAL GPIOBase API compatibilitiy
  }
  void _writePortModes() override {
    // Write 0 to REG_CONF_P0 & REG_CONF_P1 for in-use pins that are outputs, 1 for others.
    // PCA9555 & TCA9555, Interrupt is always enabled for raising and falling edge
    uint16_t temp = ~(_portMode & _portInUse);
    I2CManager.write(_I2CAddress, 3, REG_CONF_P0, temp, temp>>8);    
  }
  void _readGpioPort(bool immediate) override {
    if (immediate) {
      uint8_t buffer[2];
      I2CManager.read(_I2CAddress, buffer, 2, 1, REG_INPUT_P0);
      _portInputState = ((uint16_t)buffer[1]<<8) | buffer[0];
      /* PCA9555 Int bug fix, from PCA9555 datasheet: "must change command byte to something besides 00h 
       * after a Read operation to the PCA9555 device or before reading from 
       * another device"
       * Recommended solution, read from REG_OUTPUT_P0, then do nothing with the received data
       * Issue not seen during testing, uncomment if needed 
       */
      //I2CManager.read(_I2CAddress, buffer, 2, 1, REG_OUTPUT_P0);
    } else {
      // Queue new request
      requestBlock.wait(); // Wait for preceding operation to complete
      // Issue new request to read GPIO register
      I2CManager.queueRequest(&requestBlock);
    }
  }
  // This function is invoked when an I/O operation on the requestBlock completes.
  void _processCompletion(uint8_t status) override {
    if (status == I2C_STATUS_OK) 
      _portInputState = ((uint16_t)inputBuffer[1]<<8) | inputBuffer[0];
    else  
      _portInputState = 0xffff;
  }
  void _setupDevice() override {
    // HAL API calls
    _writePortModes();
    _writePullups();
    _writeGpioPort();
  }
  uint8_t inputBuffer[2];
  uint8_t outputBuffer[1];
  enum {
    REG_INPUT_P0 = 0x00,
    REG_INPUT_P1 = 0x01,
    REG_OUTPUT_P0 = 0x02,
    REG_OUTPUT_P1 = 0x03,
    REG_POL_INV_P0 = 0x04,
    REG_POL_INV_P1 = 0x05,
    REG_CONF_P0 = 0x06,
    REG_CONF_P1 = 0x07,    
  };
 };
 #endif
--- a/IO_RotaryEncoder.h
+++ b/IO_RotaryEncoder.h
@ -1,4 +1,5 @@
 /*
 *  © 2023, Peter Cole. All rights reserved.
 *  © 2022, Peter Cole. All rights reserved.
 *
 *  This file is part of EX-CommandStation
@ -28,9 +29,23 @@
 * ONCHANGE(vpin) - flag when the rotary encoder position has changed from the previous position
 * IFRE(vpin, position) - test to see if specified rotary encoder position has been received
 *
-* Further to this, feedback can be sent to the rotary encoder by using 2 Vpins, and sending a SET()/RESET() to the second Vpin.
+* Feedback can also be sent to the rotary encoder by using 2 Vpins, and sending a SET()/RESET() to the second Vpin.
 * A SET(vpin) will flag that a turntable (or anything else) is in motion, and a RESET(vpin) that the motion has finished.
 *
 * In addition, defining a third Vpin will allow a position number to be sent so that when an EXRAIL automation or some other
 * activity has moved a turntable, the position can be reflected in the rotary encoder software. This can be accomplished
 * using the EXRAIL SERVO(vpin, position, profile) command, where:
 * - vpin = the third defined Vpin (any other is ignored)
 * - position = the defined position in the DCC-EX Rotary Encoder software, 0 (Home) to 255
 * - profile = Must be defined as per the SERVO() command, but is ignored as it has no relevance
 *
 * Defining in myAutomation.h requires the device driver to be included in addition to the HAL() statement. Examples:
 *
 * #include "IO_RotaryEncoder.h"
 * HAL(RotaryEncoder, 700, 1, 0x70)    // Define single Vpin, no feedback or position sent to rotary encoder software
 * HAL(RotaryEncoder, 700, 2, 0x70)    // Define two Vpins, feedback only sent to rotary encoder software
 * HAL(RotaryEncoder, 700, 3, 0x70)    // Define three Vpins, can send feedback and position update to rotary encoder software
 *
 * Refer to the documentation for further information including the valid activities and examples.
 */
@ -44,58 +59,88 @@
 class RotaryEncoder : public IODevice {
 public:
-  // Constructor
+  
  RotaryEncoder(VPIN firstVpin, int nPins, I2CAddress i2cAddress){
    _firstVpin = firstVpin;
    _nPins = nPins;
    _I2CAddress = i2cAddress;
    addDevice(this);
  }
  static void create(VPIN firstVpin, int nPins, I2CAddress i2cAddress) {
    if (checkNoOverlap(firstVpin, nPins, i2cAddress)) new RotaryEncoder(firstVpin, nPins, i2cAddress);
  }
 private:
  // Constructor
  RotaryEncoder(VPIN firstVpin, int nPins, I2CAddress i2cAddress){
    _firstVpin = firstVpin;
    _nPins = nPins;
    if (_nPins > 3) {
      _nPins = 3;
      DIAG(F("RotaryEncoder WARNING:%d vpins defined, only 3 supported"), _nPins);
    }
    _I2CAddress = i2cAddress;
    addDevice(this);
  }
  // Initiate the device
  void _begin() {
    uint8_t _status;
    // Attempt to initilalise device
    I2CManager.begin();
    if (I2CManager.exists(_I2CAddress)) {
-      byte _getVersion[1] = {RE_VER};
+      // Send RE_RDY, must receive RE_RDY to be online
-      I2CManager.read(_I2CAddress, _versionBuffer, 3, _getVersion, 1);
+      _sendBuffer[0] = RE_RDY;
-      _majorVer = _versionBuffer[0];
+      _status = I2CManager.read(_I2CAddress, _rcvBuffer, 1, _sendBuffer, 1);
-      _minorVer = _versionBuffer[1];
+      if (_status == I2C_STATUS_OK) {
-      _patchVer = _versionBuffer[2];
+        if (_rcvBuffer[0] == RE_RDY) {
-      _buffer[0] = RE_OP;
+          _sendBuffer[0] = RE_VER;
-      I2CManager.write(_I2CAddress, _buffer, 1);
+          if (I2CManager.read(_I2CAddress, _versionBuffer, 3, _sendBuffer, 1) == I2C_STATUS_OK) {
            _majorVer = _versionBuffer[0];
            _minorVer = _versionBuffer[1];
            _patchVer = _versionBuffer[2];
          }
        } else {
          DIAG(F("RotaryEncoder I2C:%s garbage received: %d"), _I2CAddress.toString(), _rcvBuffer[0]);
          _deviceState = DEVSTATE_FAILED;
          return;
        }
      } else {
        DIAG(F("RotaryEncoder I2C:%s ERROR connecting"), _I2CAddress.toString());
        _deviceState = DEVSTATE_FAILED;
        return;
      }
 #ifdef DIAG_IO
      _display();
 #endif
    } else {
-        _deviceState = DEVSTATE_FAILED;
+      DIAG(F("RotaryEncoder I2C:%s device not found"), _I2CAddress.toString());
      _deviceState = DEVSTATE_FAILED;
    }
  }
  void _loop(unsigned long currentMicros) override {
-    I2CManager.read(_I2CAddress, _buffer, 1);
+    if (_deviceState == DEVSTATE_FAILED) return;  // Return if device has failed
-    _position = _buffer[0];
+    if (_i2crb.isBusy()) return;                  // Return if I2C operation still in progress
-    // This here needs to have a change check, ie. position is a different value.
+
-  #if defined(EXRAIL_ACTIVE)
+    if (currentMicros - _lastPositionRead > _positionRefresh) {
      _lastPositionRead = currentMicros;
      _sendBuffer[0] = RE_READ;
      I2CManager.read(_I2CAddress, _rcvBuffer, 1, _sendBuffer, 1, &_i2crb); // Read position from encoder
      _position = _rcvBuffer[0];
      // If EXRAIL is active, we need to trigger the ONCHANGE() event handler if it's in use
 #if defined(EXRAIL_ACTIVE)
      if (_position != _previousPosition) {
        _previousPosition = _position;
-        RMFT2::changeEvent(_firstVpin,1);
+        RMFT2::changeEvent(_firstVpin, 1);
      } else {
-        RMFT2::changeEvent(_firstVpin,0);
+        RMFT2::changeEvent(_firstVpin, 0);
      }
-  #endif
+#endif
-    delayUntil(currentMicros + 100000);
+    }
  }
-  // Device specific read function
+  // Return the position sent by the rotary encoder software
  int _readAnalogue(VPIN vpin) override {
    if (_deviceState == DEVSTATE_FAILED) return 0;
    return _position;
  }
  // Send the feedback value to the rotary encoder software
  void _write(VPIN vpin, int value) override {
    if (vpin == _firstVpin + 1) {
      if (value != 0) value = 0x01;
@ -104,6 +149,19 @@ private:
    }
  }
  // Send a position update to the rotary encoder software
  // To be valid, must be 0 to 255, and different to the current position
  // If the current position is the same, it was initiated by the rotary encoder
  void _writeAnalogue(VPIN vpin, int position, uint8_t profile, uint16_t duration) override {
    if (vpin == _firstVpin + 2) {
      if (position >= 0 && position <= 255 && position != _position) {
        byte newPosition = position & 0xFF;
        byte _positionBuffer[2] = {RE_MOVE, newPosition};
        I2CManager.write(_I2CAddress, _positionBuffer, 2);
      }
    }
  }
  void _display() override {
    DIAG(F("Rotary Encoder I2C:%s v%d.%d.%d Configured on VPIN:%u-%d %S"), _I2CAddress.toString(), _majorVer, _minorVer, _patchVer,
      (int)_firstVpin, _firstVpin+_nPins-1, (_deviceState==DEVSTATE_FAILED) ? F("OFFLINE") : F(""));
@ -112,14 +170,21 @@ private:
  int8_t _position;
  int8_t _previousPosition = 0;
  uint8_t _versionBuffer[3];
-  uint8_t _buffer[1];
+  uint8_t _sendBuffer[1];
  uint8_t _rcvBuffer[1];
  uint8_t _majorVer = 0;
  uint8_t _minorVer = 0;
  uint8_t _patchVer = 0;
  I2CRB _i2crb;
  unsigned long _lastPositionRead = 0;
  const unsigned long _positionRefresh = 100000UL;    // Delay refreshing position for 100ms
  enum {
-    RE_VER = 0xA0,   // Flag to retrieve rotary encoder version from the device
+    RE_RDY = 0xA0,   // Flag to check if encoder is ready for operation
-    RE_OP = 0xA1,    // Flag for normal operation
+    RE_VER = 0xA1,   // Flag to retrieve rotary encoder software version
    RE_READ = 0xA2,  // Flag to read the current position of the encoder
    RE_OP = 0xA3,    // Flag for operation start/end, sent to when sending feedback on move start/end
    RE_MOVE = 0xA4,  // Flag for sending a position update from the device driver to the encoder
  };
 };
--- a/MotorDriver.cpp
+++ b/MotorDriver.cpp
@ -1,9 +1,10 @@
 /*
- *  © 2022 Paul M Antoine
+ *  © 2022-2023 Paul M Antoine
 *  © 2021 Mike S
 *  © 2021 Fred Decker
- *  © 2020-2022 Harald Barth
+ *  © 2020-2023 Harald Barth
 *  © 2020-2021 Chris Harlow
 *  © 2023 Colin Murdoch
 *  All rights reserved.
 *  
 *  This file is part of CommandStation-EX
@ -26,20 +27,23 @@
 #include "DCCWaveform.h"
 #include "DCCTimer.h"
 #include "DIAG.h"
 #include "EXRAIL2.h"
-#if defined(ARDUINO_ARCH_ESP32)
+unsigned long MotorDriver::globalOverloadStart = 0;
 #include "ESP32-fixes.h"
 #endif
 bool MotorDriver::commonFaultPin=false;
 volatile portreg_t shadowPORTA;
 volatile portreg_t shadowPORTB;
 volatile portreg_t shadowPORTC;
 #if defined(ARDUINO_ARCH_STM32)
 volatile portreg_t shadowPORTD;
 volatile portreg_t shadowPORTE;
 volatile portreg_t shadowPORTF;
 #endif
 MotorDriver::MotorDriver(int16_t power_pin, byte signal_pin, byte signal_pin2, int16_t brake_pin,
                         byte current_pin, float sense_factor, unsigned int trip_milliamps, int16_t fault_pin) {
  const FSH * warnString = F("** WARNING **");
 MotorDriver::MotorDriver(int16_t power_pin, byte signal_pin, byte signal_pin2, int8_t brake_pin,
                         byte current_pin, float sense_factor, unsigned int trip_milliamps, byte fault_pin) {
  powerPin=power_pin;
  invertPower=power_pin < 0;
  if (invertPower) {
    powerPin = 0-power_pin;
@ -69,6 +73,21 @@ MotorDriver::MotorDriver(int16_t power_pin, byte signal_pin, byte signal_pin2, i
    fastSignalPin.shadowinout = fastSignalPin.inout;
    fastSignalPin.inout = &shadowPORTC;
  }
  if (HAVE_PORTD(fastSignalPin.inout == &PORTD)) {
    DIAG(F("Found PORTD pin %d"),signalPin);
    fastSignalPin.shadowinout = fastSignalPin.inout;
    fastSignalPin.inout = &shadowPORTD;
  }
  if (HAVE_PORTE(fastSignalPin.inout == &PORTE)) {
    DIAG(F("Found PORTE pin %d"),signalPin);
    fastSignalPin.shadowinout = fastSignalPin.inout;
    fastSignalPin.inout = &shadowPORTE;
  }
  if (HAVE_PORTF(fastSignalPin.inout == &PORTF)) {
    DIAG(F("Found PORTF pin %d"),signalPin);
    fastSignalPin.shadowinout = fastSignalPin.inout;
    fastSignalPin.inout = &shadowPORTF;
  }
  signalPin2=signal_pin2;
  if (signalPin2!=UNUSED_PIN) {
@ -92,35 +111,72 @@ MotorDriver::MotorDriver(int16_t power_pin, byte signal_pin, byte signal_pin2, i
      fastSignalPin2.shadowinout = fastSignalPin2.inout;
      fastSignalPin2.inout = &shadowPORTC;
    }
    if (HAVE_PORTD(fastSignalPin2.inout == &PORTD)) {
      DIAG(F("Found PORTD pin %d"),signalPin2);
      fastSignalPin2.shadowinout = fastSignalPin2.inout;
      fastSignalPin2.inout = &shadowPORTD;
    }
    if (HAVE_PORTE(fastSignalPin2.inout == &PORTE)) {
      DIAG(F("Found PORTE pin %d"),signalPin2);
      fastSignalPin2.shadowinout = fastSignalPin2.inout;
      fastSignalPin2.inout = &shadowPORTE;
    }
    if (HAVE_PORTF(fastSignalPin2.inout == &PORTF)) {
      DIAG(F("Found PORTF pin %d"),signalPin2);
      fastSignalPin2.shadowinout = fastSignalPin2.inout;
      fastSignalPin2.inout = &shadowPORTF;
    }
  }
  else dualSignal=false; 
  brakePin=brake_pin;
  if (brake_pin!=UNUSED_PIN){
    invertBrake=brake_pin < 0;
-    brakePin=invertBrake ? 0-brake_pin : brake_pin;
+    if (invertBrake)
      brake_pin = 0-brake_pin;
    if (brake_pin > MAX_PIN)
      DIAG(F("%S Brake pin %d > %d"), warnString, brake_pin, MAX_PIN);
    brakePin=(byte)brake_pin;
    getFastPin(F("BRAKE"),brakePin,fastBrakePin);
    // if brake is used for railcom  cutout we need to do PORTX register trick here as well
    pinMode(brakePin, OUTPUT);
    setBrake(true);  // start with brake on in case we hace DC stuff going on
  } else {
    brakePin=UNUSED_PIN;
  }
  else brakePin=UNUSED_PIN;
  currentPin=current_pin;
-  if (currentPin!=UNUSED_PIN) ADCee::init(currentPin);
+  if (currentPin!=UNUSED_PIN) {
    int ret = ADCee::init(currentPin);
    if (ret < -1010) { // XXX give value a name later
      DIAG(F("ADCee::init error %d, disable current pin %d"), ret, currentPin);
      currentPin = UNUSED_PIN;
    }
  }
  senseOffset=0; // value can not be obtained until waveform is activated
-  faultPin=fault_pin;
+  if (fault_pin != UNUSED_PIN) {
-  if (faultPin != UNUSED_PIN) {
+    invertFault=fault_pin < 0;
    if (invertFault)
      fault_pin =  0-fault_pin;
    if (fault_pin > MAX_PIN)
      DIAG(F("%S Fault pin %d > %d"), warnString, fault_pin, MAX_PIN);
    faultPin=(byte)fault_pin;
    DIAG(F("Fault pin = %d invert %d"), faultPin, invertFault);
    getFastPin(F("FAULT"),faultPin, 1 /*input*/, fastFaultPin);
    pinMode(faultPin, INPUT);
  } else {
      faultPin=UNUSED_PIN;
  }
  // This conversion performed at compile time so the remainder of the code never needs
  // float calculations or libraray code. 
  senseFactorInternal=sense_factor * senseScale; 
  tripMilliamps=trip_milliamps;
-  rawCurrentTripValue=mA2raw(trip_milliamps);
+#ifdef MAX_CURRENT
  if (MAX_CURRENT > 0 && MAX_CURRENT < tripMilliamps)
    tripMilliamps = MAX_CURRENT;
 #endif
  rawCurrentTripValue=mA2raw(tripMilliamps);
  if (rawCurrentTripValue + senseOffset > ADCee::ADCmax()) {
    // This would mean that the values obtained from the ADC never
@ -135,20 +191,16 @@ MotorDriver::MotorDriver(int16_t power_pin, byte signal_pin, byte signal_pin2, i
  }
  if (currentPin==UNUSED_PIN) 
-    DIAG(F("** WARNING ** No current or short detection"));
+    DIAG(F("%S No current or short detection"), warnString);
  else  {
-    DIAG(F("Track %c, TripValue=%d"), trackLetter, rawCurrentTripValue);
+    DIAG(F("Pin %d Max %dmA (%d)"), currentPin, raw2mA(rawCurrentTripValue), rawCurrentTripValue);
    // self testing diagnostic for the non-float converters... may be removed when happy
    //  DIAG(F("senseFactorInternal=%d raw2mA(1000)=%d mA2Raw(1000)=%d"),
    //   senseFactorInternal, raw2mA(1000),mA2raw(1000));
  }
  // prepare values for current detection
  sampleDelay = 0;
  lastSampleTaken = millis();
  progTripValue = mA2raw(TRIP_CURRENT_PROG); 
 }
 bool MotorDriver::isPWMCapable() {
@ -157,7 +209,12 @@ bool MotorDriver::isPWMCapable() {
 void MotorDriver::setPower(POWERMODE mode) {
-  bool on=mode==POWERMODE::ON;
+  if (powerMode == mode) return;
  //DIAG(F("Track %c POWERMODE=%d"), trackLetter, (int)mode);
  lastPowerChange[(int)mode] = micros();
  if (mode == POWERMODE::OVERLOAD)
    globalOverloadStart = lastPowerChange[(int)mode];
  bool on=(mode==POWERMODE::ON || mode ==POWERMODE::ALERT);
  if (on) {
    // when switching a track On, we need to check the crrentOffset with the pin OFF
    if (powerMode==POWERMODE::OFF && currentPin!=UNUSED_PIN) {
@ -197,8 +254,8 @@ bool MotorDriver::canMeasureCurrent() {
  return currentPin!=UNUSED_PIN;
 }
 /*
- * Return the current reading as pin reading 0 to 1023. If the fault
+ * Return the current reading as pin reading 0 to max resolution (1024 or 4096).
- * pin is activated return a negative current to show active fault pin.
+ * If the fault pin is activated return a negative current to show active fault pin.
 * As there is no -0, cheat a little and return -1 in that case.
 * 
 * senseOffset handles the case where a shield returns values above or below 
@ -210,12 +267,17 @@ int MotorDriver::getCurrentRaw(bool fromISR) {
  (void)fromISR;
  if (currentPin==UNUSED_PIN) return 0; 
  int current;
-  current = ADCee::read(currentPin, fromISR)-senseOffset;
+  current = ADCee::read(currentPin, fromISR);
  // here one can diag raw value
  // if (fromISR == false) DIAG(F("%c: %d"), trackLetter, current);
  current = current-senseOffset;     // adjust with offset
  if (current<0) current=0-current;
-  if ((faultPin != UNUSED_PIN)  && isLOW(fastFaultPin) && powerMode==POWERMODE::ON)
+  // current >= 0 here, we use negative current as fault pin flag
  if ((faultPin != UNUSED_PIN) && powerPin) {
    if (invertFault ? isHIGH(fastFaultPin) : isLOW(fastFaultPin))
      return (current == 0 ? -1 : -current);
  }
  return current;
 }
 #ifdef ANALOG_READ_INTERRUPT
@ -252,7 +314,8 @@ void MotorDriver::startCurrentFromHW() {
 #pragma GCC pop_options
 #endif //ANALOG_READ_INTERRUPT
-#if defined(ARDUINO_ARCH_ESP32)
+#if defined(ARDUINO_ARCH_ESP32) || defined(ARDUINO_ARCH_STM32)
 #ifdef VARIABLE_TONES
 uint16_t taurustones[28] = { 165, 175, 196, 220,
 			     247, 262, 294, 330,
 			     349, 392, 440, 494,
@ -261,29 +324,58 @@ uint16_t taurustones[28] = { 165, 175, 196, 220,
 			     330, 284, 262, 247,
 			     220, 196, 175, 165 };
 #endif
 #endif
 void MotorDriver::setDCSignal(byte speedcode) {
  if (brakePin == UNUSED_PIN)
    return;
  switch(brakePin) {
 #if defined(ARDUINO_AVR_UNO)
-  TCCR2B = (TCCR2B & B11111000) | B00000110; // set divisor on timer 2 to result in (approx) 122.55Hz
+    // Not worth doin something here as:
    // If we are on pin 9 or 10 we are on Timer1 and we can not touch Timer1 as that is our DCC source.
    // If we are on pin 5 or 6 we are on Timer 0 ad we can not touch Timer0 as that is millis() etc.
    // We are most likely not on pin 3 or 11 as no known motor shield has that as brake.
 #endif
 #if defined(ARDUINO_AVR_MEGA) || defined(ARDUINO_AVR_MEGA2560)
-  TCCR2B = (TCCR2B & B11111000) | B00000110; // set divisor on timer 2 to result in (approx) 122.55Hz
+  case 9:
-  TCCR4B = (TCCR4B & B11111000) | B00000100; // same for timer 4 but maxcount and thus divisor differs
+  case 10:
    // Timer2 (is differnet)
    TCCR2A = (TCCR2A & B11111100) | B00000001; // set WGM1=0 and WGM0=1 phase correct PWM
    TCCR2B = (TCCR2B & B11110000) | B00000110; // set WGM2=0 ; set divisor on timer 2 to 1/256 for 122.55Hz
    //DIAG(F("2 A=%x B=%x"), TCCR2A, TCCR2B);
    break;
  case 6:
  case 7:
  case 8:
    // Timer4
    TCCR4A = (TCCR4A & B11111100) | B00000001; // set WGM0=1 and WGM1=0 for normal PWM 8-bit
    TCCR4B = (TCCR4B & B11100000) | B00000100; // set WGM2=0 and WGM3=0 for normal PWM 8 bit and div 1/256 for 122.55Hz
    break;
  case 46:
  case 45:
  case 44:
    // Timer5
    TCCR5A = (TCCR5A & B11111100) | B00000001; // set WGM0=1 and WGM1=0 for normal PWM 8-bit
    TCCR5B = (TCCR5B & B11100000) | B00000100; // set WGM2=0 and WGM3=0 for normal PWM 8 bit and div 1/256 for 122.55Hz
    break;
 #endif
  default:
    break;
  }
  // spedcoode is a dcc speed & direction
  byte tSpeed=speedcode & 0x7F; // DCC Speed with 0,1 stop and speed steps 2 to 127
  byte tDir=speedcode & 0x80;
  byte brake;
-#if defined(ARDUINO_ARCH_ESP32)
+#if defined(ARDUINO_ARCH_ESP32) || defined(ARDUINO_ARCH_STM32)
  {
    int f = 131;
 #ifdef VARIABLE_TONES
    if (tSpeed > 2) {
      if (tSpeed <= 58) {
 	f = taurustones[ (tSpeed-2)/2 ] ;
      }
    }
-    DCCEXanalogWriteFrequency(brakePin, f); // set DC PWM frequency to 100Hz XXX May move to setup
+#endif
    DCCTimer::DCCEXanalogWriteFrequency(brakePin, f); // set DC PWM frequency to 100Hz XXX May move to setup
  }
 #endif
  if (tSpeed <= 1) brake = 255;
@ -291,8 +383,8 @@ void MotorDriver::setDCSignal(byte speedcode) {
  else  brake = 2 * (128-tSpeed);
  if (invertBrake)
    brake=255-brake;
-#if defined(ARDUINO_ARCH_ESP32)
+#if defined(ARDUINO_ARCH_ESP32) || defined(ARDUINO_ARCH_STM32)
-  DCCEXanalogWrite(brakePin,brake);
+  DCCTimer::DCCEXanalogWrite(brakePin,brake);
 #else
  analogWrite(brakePin,brake);
 #endif
@ -315,13 +407,91 @@ void MotorDriver::setDCSignal(byte speedcode) {
    setSignal(tDir);
    HAVE_PORTC(PORTC=shadowPORTC);
    interrupts();
  } else if (HAVE_PORTD(fastSignalPin.shadowinout == &PORTD)) {
    noInterrupts();
    HAVE_PORTD(shadowPORTD=PORTD);
    setSignal(tDir);
    HAVE_PORTD(PORTD=shadowPORTD);
    interrupts();
  } else if (HAVE_PORTE(fastSignalPin.shadowinout == &PORTE)) {
    noInterrupts();
    HAVE_PORTE(shadowPORTE=PORTE);
    setSignal(tDir);
    HAVE_PORTE(PORTE=shadowPORTE);
    interrupts();
  } else if (HAVE_PORTF(fastSignalPin.shadowinout == &PORTF)) {
    noInterrupts();
    HAVE_PORTF(shadowPORTF=PORTF);
    setSignal(tDir);
    HAVE_PORTF(PORTF=shadowPORTF);
    interrupts();
  } else {
    noInterrupts();
    setSignal(tDir);
    interrupts();
  }
 }
-
+void MotorDriver::throttleInrush(bool on) {
  if (brakePin == UNUSED_PIN)
    return;
  if ( !(trackMode & (TRACK_MODE_MAIN | TRACK_MODE_PROG | TRACK_MODE_EXT)))
    return;
  byte duty = on ? 208 : 0;
  if (invertBrake)
    duty = 255-duty;
 #if defined(ARDUINO_ARCH_ESP32)
  if(on) {
    DCCTimer::DCCEXanalogWrite(brakePin,duty);
    DCCTimer::DCCEXanalogWriteFrequency(brakePin, 62500);
  } else {
    ledcDetachPin(brakePin);
  }
 #elif defined(ARDUINO_ARCH_STM32)
  if(on) {
    DCCTimer::DCCEXanalogWriteFrequency(brakePin, 62500);
    DCCTimer::DCCEXanalogWrite(brakePin,duty);
  } else {
    pinMode(brakePin, OUTPUT);
  }
 #else
  if(on){
    switch(brakePin) {
 #if defined(ARDUINO_AVR_UNO)
      // Not worth doin something here as:
      // If we are on pin 9 or 10 we are on Timer1 and we can not touch Timer1 as that is our DCC source.
      // If we are on pin 5 or 6 we are on Timer 0 ad we can not touch Timer0 as that is millis() etc.
      // We are most likely not on pin 3 or 11 as no known motor shield has that as brake.
 #endif
 #if defined(ARDUINO_AVR_MEGA) || defined(ARDUINO_AVR_MEGA2560)
    case 9:
    case 10:
      // Timer2 (is different)
      TCCR2A = (TCCR2A & B11111100) | B00000011; // set WGM0=1 and WGM1=1 for fast PWM
      TCCR2B = (TCCR2B & B11110000) | B00000001; // set WGM2=0 and prescaler div=1 (max)
      DIAG(F("2 A=%x B=%x"), TCCR2A, TCCR2B);
      break;
    case 6:
    case 7:
    case 8:
      // Timer4
      TCCR4A = (TCCR4A & B11111100) | B00000001; // set WGM0=1 and WGM1=0 for fast PWM 8-bit
      TCCR4B = (TCCR4B & B11100000) | B00001001; // set WGM2=1 and WGM3=0 for fast PWM 8 bit and div=1 (max)
      break;
    case 46:
    case 45:
    case 44:
      // Timer5
      TCCR5A = (TCCR5A & B11111100) | B00000001; // set WGM0=1 and WGM1=0 for fast PWM 8-bit
      TCCR5B = (TCCR5B & B11100000) | B00001001; // set WGM2=1 and WGM3=0 for fast PWM 8 bit and div=1 (max)
      break;
 #endif
    default:
      break;
    }
  }
  analogWrite(brakePin,duty);
 #endif
 }
 unsigned int MotorDriver::raw2mA( int raw) {
  //DIAG(F("%d = %d * %d / %d"), (int32_t)raw * senseFactorInternal / senseScale, raw, senseFactorInternal, senseScale);
  return (int32_t)raw * senseFactorInternal / senseScale;
@ -350,64 +520,172 @@ void  MotorDriver::getFastPin(const FSH* type,int pin, bool input, FASTPIN & res
    // DIAG(F(" port=0x%x, inoutpin=0x%x, isinput=%d, mask=0x%x"),port, result.inout,input,result.maskHIGH);
 }
-void MotorDriver::checkPowerOverload(bool useProgLimit, byte trackno) {
+///////////////////////////////////////////////////////////////////////////////////////////
-  if (millis() - lastSampleTaken  < sampleDelay) return;
+// checkPowerOverload(useProgLimit, trackno)
-  lastSampleTaken = millis();
+// bool useProgLimit: Trackmanager knows if this track is in prog mode or in main mode
-  int tripValue= useProgLimit?progTripValue:getRawCurrentTripValue();
+// byte trackno: trackmanager knows it's number (could be skipped?)
 //
 // Short ciruit handling strategy:
 //
 // There are the following power states: ON ALERT OVERLOAD OFF
 // OFF state is only changed to/from manually. Power is on
 // during ON and ALERT. Power is off during OVERLOAD and OFF.
 // The overload mechanism changes between the other states like
 //
 // ON -1-> ALERT -2-> OVERLOAD -3-> ALERT -4-> ON
 // or
 // ON -1-> ALERT -4-> ON
 //
 // Times are in class MotorDriver (MotorDriver.h).
 //
 // 1. ON to ALERT:
 // Transition on fault pin condition or current overload
 //
 // 2. ALERT to OVERLOAD:
 // Transition happens if different timeouts have elapsed.
 // If only the fault pin is active, timeout is
 // POWER_SAMPLE_IGNORE_FAULT_LOW (100ms)
 // If only overcurrent is detected, timeout is
 // POWER_SAMPLE_IGNORE_CURRENT (100ms)
 // If fault pin and overcurrent are active, timeout is
 // POWER_SAMPLE_IGNORE_FAULT_HIGH (5ms)
 // Transition to OVERLOAD turns off power to the affected
 // output (unless fault pins are shared)
 // If the transition conditions are not fullfilled,
 // transition according to 4 is tested.
 //
 // 3. OVERLOAD to ALERT
 // Transiton happens when timeout has elapsed, timeout
 // is named power_sample_overload_wait. It is started
 // at POWER_SAMPLE_OVERLOAD_WAIT (40ms) at first entry
 // to OVERLOAD and then increased by a factor of 2
 // at further entries to the OVERLOAD condition. This
 // happens until POWER_SAMPLE_RETRY_MAX (10sec) is reached.
 // power_sample_overload_wait is reset by a poweroff or
 // a POWER_SAMPLE_ALL_GOOD (5sec) period during ON.
 // After timeout power is turned on again and state
 // goes back to ALERT.
 //
 // 4. ALERT to ON
 // Transition happens by watching the current and fault pin
 // samples during POWER_SAMPLE_ALERT_GOOD (20ms) time. If
 // values have been good during that time, transition is
 // made back to ON. Note that even if state is back to ON,
 // the power_sample_overload_wait time is first reset
 // later (see above).
 //
 // The time keeping is handled by timestamps lastPowerChange[]
 // which are set by each power change and by lastBadSample which
 // keeps track if conditions during ALERT have been good enough
 // to go back to ON. The time differences are calculated by
 // microsSinceLastPowerChange().
 //
 void MotorDriver::checkPowerOverload(bool useProgLimit, byte trackno) {
  // Trackname for diag messages later
  switch (powerMode) {
-    case POWERMODE::OFF:
+
-      sampleDelay = POWER_SAMPLE_OFF_WAIT;
+  case POWERMODE::OFF: {
-      break;
+    lastPowerMode = POWERMODE::OFF;
-    case POWERMODE::ON:
+    power_sample_overload_wait = POWER_SAMPLE_OVERLOAD_WAIT;
-      // Check current
+    break;
-      lastCurrent=getCurrentRaw();
+  }
-      if (lastCurrent < 0) {
+
-	  // We have a fault pin condition to take care of
+  case POWERMODE::ON: {
-	  lastCurrent = -lastCurrent;
+    lastPowerMode = POWERMODE::ON;
-	  setPower(POWERMODE::OVERLOAD); // Turn off, decide later how fast to turn on again
+    bool cF = checkFault();
-	  if (commonFaultPin) {
+    bool cC = checkCurrent(useProgLimit);
-	      if (lastCurrent < tripValue) {
+    if(cF || cC ) {
-		      setPower(POWERMODE::ON); // maybe other track
+      if (cC) {
-	      }
+	unsigned int mA=raw2mA(lastCurrent);
-	      // Write this after the fact as we want to turn on as fast as possible
+	DIAG(F("TRACK %c ALERT %s %dmA"), trackno + 'A',
-	      // because we don't know which output actually triggered the fault pin
+	     cF ? "FAULT" : "",
-	      DIAG(F("COMMON FAULT PIN ACTIVE: POWERTOGGLE TRACK %c"), trackno + 'A');
+	     mA);
 	  } else {
 	    DIAG(F("TRACK %c FAULT PIN ACTIVE - OVERLOAD"), trackno + 'A');
 	      if (lastCurrent < tripValue) {
 		  lastCurrent = tripValue; // exaggerate
 	      }
 	  }
      }
      if (lastCurrent < tripValue) {
        sampleDelay = POWER_SAMPLE_ON_WAIT;
 	if(power_good_counter<100)
 	  power_good_counter++;
 	else
 	  if (power_sample_overload_wait>POWER_SAMPLE_OVERLOAD_WAIT) power_sample_overload_wait=POWER_SAMPLE_OVERLOAD_WAIT;
      } else {
-        setPower(POWERMODE::OVERLOAD);
+	DIAG(F("TRACK %c ALERT FAULT"), trackno + 'A');
        unsigned int mA=raw2mA(lastCurrent);
        unsigned int maxmA=raw2mA(tripValue);
 	      power_good_counter=0;
        sampleDelay = power_sample_overload_wait;
        DIAG(F("TRACK %c POWER OVERLOAD %dmA (limit %dmA) shutdown for %dms"), trackno + 'A', mA, maxmA, sampleDelay);
 	if (power_sample_overload_wait >= 10000)
 	    power_sample_overload_wait = 10000;
 	else
 	    power_sample_overload_wait *= 2;
      }
      setPower(POWERMODE::ALERT);
      break;
-    case POWERMODE::OVERLOAD:
+    }
-      // Try setting it back on after the OVERLOAD_WAIT
+    // all well
    if (microsSinceLastPowerChange(POWERMODE::ON) > POWER_SAMPLE_ALL_GOOD) {
      power_sample_overload_wait = POWER_SAMPLE_OVERLOAD_WAIT;
    }
    break;
  }
  case POWERMODE::ALERT: {
    // set local flags that handle how much is output to diag (do not output duplicates)
    bool notFromOverload = (lastPowerMode != POWERMODE::OVERLOAD);
    bool powerModeChange = (powerMode != lastPowerMode);
    unsigned long now = micros();
    if (powerModeChange)
      lastBadSample = now;
    lastPowerMode = POWERMODE::ALERT;
    // check how long we have been in this state
    unsigned long mslpc = microsSinceLastPowerChange(POWERMODE::ALERT);
    if(checkFault()) {
      throttleInrush(true);
      lastBadSample = now;
      unsigned long timeout = checkCurrent(useProgLimit) ? POWER_SAMPLE_IGNORE_FAULT_HIGH : POWER_SAMPLE_IGNORE_FAULT_LOW;
      if ( mslpc < timeout) {
 	if (powerModeChange)
 	  DIAG(F("TRACK %c FAULT PIN (%M ignore)"), trackno + 'A', timeout);
 	break;
      }
      DIAG(F("TRACK %c FAULT PIN detected after %4M. Pause %4M)"), trackno + 'A', mslpc, power_sample_overload_wait);
      throttleInrush(false);
      setPower(POWERMODE::OVERLOAD);
      break;
    }
    if (checkCurrent(useProgLimit)) {
      lastBadSample = now;
      if (mslpc < POWER_SAMPLE_IGNORE_CURRENT) {
 	if (powerModeChange) {
 	  unsigned int mA=raw2mA(lastCurrent);
 	  DIAG(F("TRACK %c CURRENT (%M ignore) %dmA"), trackno + 'A', POWER_SAMPLE_IGNORE_CURRENT, mA);
 	}
 	break;
      }
      unsigned int mA=raw2mA(lastCurrent);
      unsigned int maxmA=raw2mA(tripValue);
      DIAG(F("TRACK %c POWER OVERLOAD %4dmA (max %4dmA) detected after %4M. Pause %4M"),
 	   trackno + 'A', mA, maxmA, mslpc, power_sample_overload_wait);
      throttleInrush(false);
      setPower(POWERMODE::OVERLOAD);
      break;
    }
    // all well
    unsigned long goodtime = micros() - lastBadSample;
    if (goodtime > POWER_SAMPLE_ALERT_GOOD) {
      if (true || notFromOverload) { // we did a RESTORE message XXX
 	unsigned int mA=raw2mA(lastCurrent);
 	DIAG(F("TRACK %c NORMAL (after %M/%M) %dmA"), trackno + 'A', goodtime, mslpc, mA);
      }
      throttleInrush(false);
      setPower(POWERMODE::ON);
-      sampleDelay = POWER_SAMPLE_ON_WAIT;
+    }
-      // Debug code....
+    break;
-      DIAG(F("TRACK %c POWER RESTORE (check %dms)"), trackno + 'A', sampleDelay);
+  }
-      break;
+
-    default:
+  case POWERMODE::OVERLOAD: {
-      sampleDelay = 999; // cant get here..meaningless statement to avoid compiler warning.
+    lastPowerMode = POWERMODE::OVERLOAD;
    unsigned long mslpc = (commonFaultPin ? (micros() - globalOverloadStart) : microsSinceLastPowerChange(POWERMODE::OVERLOAD));
    if (mslpc > power_sample_overload_wait) {
      // adjust next wait time
      power_sample_overload_wait *= 2;
      if (power_sample_overload_wait > POWER_SAMPLE_RETRY_MAX)
 	      power_sample_overload_wait = POWER_SAMPLE_RETRY_MAX;
      DIAG(F("Calling EXRAIL"));
      RMFT2::powerEvent(trackno, true); // Tell EXRAIL we have an overload
      // power on test
      DIAG(F("TRACK %c POWER RESTORE (after %4M)"), trackno + 'A', mslpc);
      setPower(POWERMODE::ALERT);
    }
    break;
  }
  default:
    break;
  }
 }
--- a/MotorDriver.h
+++ b/MotorDriver.h
@ -1,5 +1,5 @@
 /*
- *  © 2022 Paul M Antoine
+ *  © 2022-2023 Paul M. Antoine
 *  © 2021 Mike S
 *  © 2021 Fred Decker
 *  © 2020 Chris Harlow
@ -27,6 +27,10 @@
 #include "IODevice.h"
 #include "DCCTimer.h"
 // use powers of two so we can do logical and/or on the track modes in if clauses.
 enum TRACK_MODE : byte {TRACK_MODE_NONE = 1, TRACK_MODE_MAIN = 2, TRACK_MODE_PROG = 4,
                        TRACK_MODE_DC = 8, TRACK_MODE_DCX = 16, TRACK_MODE_EXT = 32};
 #define setHIGH(fastpin)  *fastpin.inout |= fastpin.maskHIGH
 #define setLOW(fastpin)   *fastpin.inout &= fastpin.maskLOW
 #define isHIGH(fastpin)   (*fastpin.inout & fastpin.maskHIGH)
@ -56,6 +60,16 @@
 #define HAVE_PORTB(X) X
 #define PORTC GPIOC->ODR
 #define HAVE_PORTC(X) X
 #define PORTD GPIOD->ODR
 #define HAVE_PORTD(X) X
 #if defined(GPIOE)
 #define PORTE GPIOE->ODR
 #define HAVE_PORTE(X) X
 #endif
 #if defined(GPIOF)
 #define PORTF GPIOF->ODR
 #define HAVE_PORTF(X) X
 #endif
 #endif
 // if macros not defined as pass-through we define
@ -70,12 +84,22 @@
 #ifndef HAVE_PORTC
 #define HAVE_PORTC(X) byte TOKENPASTE2(Unique_, __LINE__) __attribute__((unused)) =0
 #endif
 #ifndef HAVE_PORTD
 #define HAVE_PORTD(X) byte TOKENPASTE2(Unique_, __LINE__) __attribute__((unused)) =0
 #endif
 #ifndef HAVE_PORTE
 #define HAVE_PORTE(X) byte TOKENPASTE2(Unique_, __LINE__) __attribute__((unused)) =0
 #endif
 #ifndef HAVE_PORTF
 #define HAVE_PORTF(X) byte TOKENPASTE2(Unique_, __LINE__) __attribute__((unused)) =0
 #endif
 // Virtualised Motor shield 1-track hardware Interface
 #ifndef UNUSED_PIN     // sync define with the one in MotorDrivers.h
-#define UNUSED_PIN 127 // inside int8_t
+#define UNUSED_PIN 255 // inside uint8_t
 #endif
 #define MAX_PIN 254
 class pinpair {
 public:
@ -105,14 +129,17 @@ struct FASTPIN {
 extern volatile portreg_t shadowPORTA;
 extern volatile portreg_t shadowPORTB;
 extern volatile portreg_t shadowPORTC;
 extern volatile portreg_t shadowPORTD;
 extern volatile portreg_t shadowPORTE;
 extern volatile portreg_t shadowPORTF;
-enum class POWERMODE : byte { OFF, ON, OVERLOAD };
+enum class POWERMODE : byte { OFF, ON, OVERLOAD, ALERT };
 class MotorDriver {
  public:
-    MotorDriver(int16_t power_pin, byte signal_pin, byte signal_pin2, int8_t brake_pin, 
+    MotorDriver(int16_t power_pin, byte signal_pin, byte signal_pin2, int16_t brake_pin, 
-                byte current_pin, float senseFactor, unsigned int tripMilliamps, byte faultPin);
+                byte current_pin, float senseFactor, unsigned int tripMilliamps, int16_t fault_pin);
    void setPower( POWERMODE mode);
    POWERMODE getPower() { return powerMode;}
    // as the port registers can be shadowed to get syncronized DCC signals
@ -144,6 +171,7 @@ class MotorDriver {
    };
    inline pinpair getSignalPin() { return pinpair(signalPin,signalPin2); };
    void setDCSignal(byte speedByte);
    void throttleInrush(bool on);
    inline void detachDCSignal() {
 #if defined(__arm__)
      pinMode(brakePin, OUTPUT);
@ -157,16 +185,16 @@ class MotorDriver {
    unsigned int raw2mA( int raw);
    unsigned int mA2raw( unsigned int mA);
    inline bool brakeCanPWM() {
-#if defined(ARDUINO_ARCH_ESP32) || defined(__arm__)
+#if defined(ARDUINO_ARCH_ESP32)
-      // TODO: on ARM we can use digitalPinHasPWM, and may wish/need to
+      return (brakePin != UNUSED_PIN); // This was just (true) but we probably do need to check for UNUSED_PIN!
-      return true;
+#elif defined(__arm__)
-#else
+      // On ARM we can use digitalPinHasPWM
-#ifdef digitalPinToTimer
+      return ((brakePin!=UNUSED_PIN) && (digitalPinHasPWM(brakePin)));
 #elif defined(digitalPinToTimer)
      return ((brakePin!=UNUSED_PIN) && (digitalPinToTimer(brakePin)));
 #else
      return (brakePin<14 && brakePin >1);
-#endif //digitalPinToTimer
+#endif
 #endif //ESP32/ARM
    }
    inline int getRawCurrentTripValue() {
 	    return rawCurrentTripValue;
@ -174,7 +202,10 @@ class MotorDriver {
    bool isPWMCapable();
    bool canMeasureCurrent();
    bool trackPWM = false; // this track uses PWM timer to generate the DCC waveform
-    static bool commonFaultPin; // This is a stupid motor shield which has only a common fault pin for both outputs
+    bool commonFaultPin = false; // This is a stupid motor shield which has only a common fault pin for both outputs
    inline byte setCommonFaultPin() {
      return commonFaultPin = true;
    }
    inline byte getFaultPin() {
 	return faultPin;
    }
@ -185,23 +216,53 @@ class MotorDriver {
    inline void setTrackLetter(char c) {
      trackLetter = c;
    };
    // this returns how much time has passed since the last power change. If it
    // was really long ago (approx > 52min) advance counter approx 35 min so that
    // we are at 18 minutes again. Times for 32 bit unsigned long.
    inline unsigned long microsSinceLastPowerChange(POWERMODE mode) {
      unsigned long now = micros();
      unsigned long diff = now - lastPowerChange[(int)mode];
      if (diff > (1UL << (7 *sizeof(unsigned long)))) // 2^(4*7)us = 268.4 seconds
        lastPowerChange[(int)mode] = now - 30000000UL;           // 30 seconds ago
      return diff;
    };
 #ifdef ANALOG_READ_INTERRUPT
    bool sampleCurrentFromHW();
    void startCurrentFromHW();
 #endif
  inline void setMode(TRACK_MODE m) {
    trackMode = m;
  };
  inline TRACK_MODE getMode() {
    return trackMode;
  };
  private:
    char trackLetter = '?';
    bool isProgTrack = false; // tells us if this is a prog track
    void  getFastPin(const FSH* type,int pin, bool input, FASTPIN & result);
-    void  getFastPin(const FSH* type,int pin, FASTPIN & result) {
+    inline void  getFastPin(const FSH* type,int pin, FASTPIN & result) {
 	getFastPin(type, pin, 0, result);
-    }
+    };
    // side effect sets lastCurrent and tripValue
    inline bool checkCurrent(bool useProgLimit) {
      tripValue= useProgLimit?progTripValue:getRawCurrentTripValue();
      lastCurrent = getCurrentRaw();
      if (lastCurrent < 0)
 	lastCurrent = -lastCurrent;
      return lastCurrent >= tripValue;
    };
    // side effect sets lastCurrent
    inline bool checkFault() {
      lastCurrent = getCurrentRaw();
      return lastCurrent < 0;
    };
    VPIN powerPin;
    byte signalPin, signalPin2, currentPin, faultPin, brakePin;
    FASTPIN fastSignalPin, fastSignalPin2, fastBrakePin,fastFaultPin;
    bool dualSignal;       // true to use signalPin2
    bool invertBrake;       // brake pin passed as negative means pin is inverted
    bool invertPower;       // power pin passed as negative means pin is inverted
    bool invertFault;       // fault pin passed as negative means pin is inverted
    // Raw to milliamp conversion factors avoiding float data types.
    // Milliamps=rawADCreading * sensefactorInternal / senseScale
@ -215,10 +276,14 @@ class MotorDriver {
    int rawCurrentTripValue;
    // current sampling
    POWERMODE powerMode;
-    unsigned long lastSampleTaken;
+    POWERMODE lastPowerMode;
-    unsigned int sampleDelay;
+    unsigned long lastPowerChange[4];         // timestamp in microseconds
    unsigned long lastBadSample;              // timestamp in microseconds
    // used to sync restore time when common Fault pin detected
    static unsigned long globalOverloadStart; // timestamp in microseconds
    int progTripValue;
-    int  lastCurrent;
+    int  lastCurrent; //temp value
    int  tripValue;   //temp value
 #ifdef ANALOG_READ_INTERRUPT
    volatile unsigned long sampleCurrentTimestamp;
    volatile uint16_t sampleCurrent;
@ -226,16 +291,28 @@ class MotorDriver {
    int maxmA;
    int tripmA;
-    // Wait times for power management. Unit: milliseconds
+    // Times for overload management. Unit: microseconds.
-    static const int  POWER_SAMPLE_ON_WAIT = 100;
+    // Base for wait time until power is turned on again
-    static const int  POWER_SAMPLE_OFF_WAIT = 1000;
+    static const unsigned long POWER_SAMPLE_OVERLOAD_WAIT =     40000UL;
-    static const int  POWER_SAMPLE_OVERLOAD_WAIT = 20;
+    // Time after we consider all faults old and forgotten
    static const unsigned long POWER_SAMPLE_ALL_GOOD =        5000000UL;
    // Time after which we consider a ALERT over 
    static const unsigned long POWER_SAMPLE_ALERT_GOOD =        20000UL;
    // How long to ignore fault pin if current is under limit
    static const unsigned long POWER_SAMPLE_IGNORE_FAULT_LOW = 100000UL;
    // How long to ignore fault pin if current is higher than limit
    static const unsigned long POWER_SAMPLE_IGNORE_FAULT_HIGH =  5000UL;
    // How long to wait between overcurrent and turning off
    static const unsigned long POWER_SAMPLE_IGNORE_CURRENT  =  100000UL;
    // Upper limit for retry period
    static const unsigned long POWER_SAMPLE_RETRY_MAX =      10000000UL;
    // Trip current for programming track, 250mA. Change only if you really
    // need to be non-NMRA-compliant because of decoders that are not either.
    static const int TRIP_CURRENT_PROG=250;
    unsigned long power_sample_overload_wait = POWER_SAMPLE_OVERLOAD_WAIT;
    unsigned int power_good_counter = 0;
    TRACK_MODE trackMode = TRACK_MODE_NONE; // we assume track not assigned at startup
 };
 #endif
--- a/MotorDrivers.h
+++ b/MotorDrivers.h
@ -1,7 +1,7 @@
 /*
- *  © 2022 Paul M. Antoine
+ *  © 2022-2023 Paul M. Antoine
 *  © 2021 Fred Decker
- *  © 2020-2022 Harald Barth
+ *  © 2020-2023 Harald Barth
 *  (c) 2020 Chris Harlow. All rights reserved.
 *  (c) 2021 Fred Decker.  All rights reserved.
 *  (c) 2020 Harald Barth. All rights reserved.
@ -36,7 +36,7 @@
 // custom defines in config.h.
 #ifndef UNUSED_PIN     // sync define with the one in MotorDriver.h
-#define UNUSED_PIN 127 // inside int8_t
+#define UNUSED_PIN 255 // inside uint8_t
 #endif
 // The MotorDriver definition is:
@ -60,7 +60,8 @@
 // Arduino STANDARD Motor Shield, used on different architectures:
 #if defined(ARDUINO_ARCH_SAMD) || defined(ARDUINO_ARCH_STM32)
-// Setup for SAMD21 Sparkfun DEV board using Arduino standard Motor Shield R3 (MUST be R3
+// Standard Motor Shield definition for 3v3 processors (other than the ESP32)
 // Setup for SAMD21 Sparkfun DEV board MUST use Arduino Motor Shield R3 (MUST be R3
 // for 3v3 compatibility!!) senseFactor for 3.3v systems is 1.95 as calculated when using
 // 10-bit A/D samples, and for 12-bit samples it's more like 0.488, but we probably need
 // to tweak both these
@ -70,15 +71,27 @@
 #define SAMD_STANDARD_MOTOR_SHIELD STANDARD_MOTOR_SHIELD
 #define STM32_STANDARD_MOTOR_SHIELD STANDARD_MOTOR_SHIELD
 // EX 8874 based shield connected to a 3V3 system with 12-bit (4096) ADC
 #define EX8874_SHIELD F("EX8874"), \
 new MotorDriver( 3, 12, UNUSED_PIN, 9, A0, 1.27, 5000, A4), \
 new MotorDriver(11, 13, UNUSED_PIN, 8, A1, 1.27, 5000, A5)
 #elif defined(ARDUINO_ARCH_ESP32)
 // STANDARD shield on an ESPDUINO-32 (ESP32 in Uno form factor). The shield must be eiter the
 // 3.3V compatible R3 version or it has to be modified to not supply more than 3.3V to the
 // analog inputs. Here we use analog inputs A2 and A3 as A0 and A1 are wired in a way so that
 // they are not useable at the same time as WiFi (what a bummer). The numbers below are the
 // actual GPIO numbers. In comments the numbers the pins have on an Uno.
-#define STANDARD_MOTOR_SHIELD F("STANDARD_MOTOR_SHIELD"),                                                 \
+#define STANDARD_MOTOR_SHIELD F("STANDARD_MOTOR_SHIELD"), \
-    new MotorDriver(25/* 3*/, 19/*12*/, UNUSED_PIN, 13/*9*/, 35/*A2*/, 0.70, 1500, UNUSED_PIN), \
+ new MotorDriver(25/* 3*/, 19/*12*/, UNUSED_PIN, 13/*9*/, 35/*A2*/, 0.70, 1500, UNUSED_PIN), \
-    new MotorDriver(23/*11*/, 18/*13*/, UNUSED_PIN, 12/*8*/, 34/*A3*/, 0.70, 1500, UNUSED_PIN)
+ new MotorDriver(23/*11*/, 18/*13*/, UNUSED_PIN, 12/*8*/, 34/*A3*/, 0.70, 1500, UNUSED_PIN)
 // EX 8874 based shield connected to a 3.3V system (like ESP32) and 12bit (4096) ADC
 // numbers are GPIO numbers. comments are UNO form factor shield pin numbers
 #define EX8874_SHIELD F("EX8874"),\
 new MotorDriver(25/* 3*/, 19/*12*/, UNUSED_PIN, 13/*9*/, 35/*A2*/, 1.27, 5000, 36 /*A4*/), \
 new MotorDriver(23/*11*/, 18/*13*/, UNUSED_PIN, 12/*8*/, 34/*A3*/, 1.27, 5000, 39 /*A5*/)
 #else
 // STANDARD shield on any Arduino Uno or Mega compatible with the original specification.
@ -88,6 +101,12 @@
 #define BRAKE_PWM_SWAPPED_MOTOR_SHIELD F("BPS_MOTOR_SHIELD"),                                       \
                              new MotorDriver(-9 , 12, UNUSED_PIN, -3, A0, 2.99, 1500, UNUSED_PIN), \
                              new MotorDriver(-8 , 13, UNUSED_PIN,-11, A1, 2.99, 1500, UNUSED_PIN)
 // EX 8874 based shield connected to a 5V system (like Arduino) and 10bit (1024) ADC
 #define EX8874_SHIELD F("EX8874"), \
 new MotorDriver( 3, 12, UNUSED_PIN, 9, A0, 5.08, 5000, A4), \
 new MotorDriver(11, 13, UNUSED_PIN, 8, A1, 5.08, 5000, A5)
 #endif
 // Pololu Motor Shield
--- a/SerialManager.cpp
+++ b/SerialManager.cpp
@ -87,6 +87,9 @@ void SerialManager::init() {
    delay(1000);
  }
 #endif
 #ifdef SABERTOOTH
  Serial2.begin(9600, SERIAL_8N1, 16, 17); // GPIO 16 RXD2; GPIO 17 TXD2 on ESP32
 #endif
 }
 void SerialManager::broadcast(char * stringBuffer) {
--- a/StringFormatter.cpp
+++ b/StringFormatter.cpp
@ -117,6 +117,25 @@ void StringFormatter::send2(Print * stream,const FSH* format, va_list args) {
      case 'o': stream->print(va_arg(args, int), OCT); break;
      case 'x': stream->print((unsigned int)va_arg(args, unsigned int), HEX); break;
      case 'X': stream->print((unsigned long)va_arg(args, unsigned long), HEX); break;
      case 'h': printHex(stream,(unsigned int)va_arg(args, unsigned int)); break;
      case 'M':
      { // this prints a unsigned long microseconds time in readable format
 	unsigned long time = va_arg(args, long);
 	if (time >= 2000) {
 	  time = time / 1000;
 	  if (time >= 2000) {
 	    printPadded(stream, time/1000, formatWidth, formatLeft);
 	    stream->print(F("sec"));
 	  } else {
 	    printPadded(stream,time, formatWidth, formatLeft);
 	    stream->print(F("msec"));
 	  }
 	} else {
 	  printPadded(stream,time, formatWidth, formatLeft);
 	  stream->print(F("usec"));
 	}
      }
      break;
      //case 'f': stream->print(va_arg(args, double), 2); break;
      //format width prefix
      case '-': 
@ -200,4 +219,15 @@ void StringFormatter::printPadded(Print* stream, long value, byte width, bool fo
    if (!formatLeft) stream->print(value, DEC);    
  }
 // printHex prints the full 2 byte hex with leading zeros, unlike print(value,HEX)
 const char FLASH hexchars[]="0123456789ABCDEF";
 void StringFormatter::printHex(Print * stream,uint16_t value) {
    char result[5];
    for (int i=3;i>=0;i--) {
      result[i]=GETFLASH(hexchars+(value & 0x0F));
      value>>=4;
    }
    result[4]='\0';
     stream->print(result);
 }
--- a/StringFormatter.h
+++ b/StringFormatter.h
@ -49,6 +49,7 @@ class StringFormatter
    static void lcd2(uint8_t display, byte row, const FSH* input...);
    static void printEscapes(char * input);
    static void printEscape( char c);
    static void printHex(Print * stream,uint16_t value);
    private: 
    static void send2(Print * serial, const FSH* input,va_list args);
--- a/TrackManager.cpp
+++ b/TrackManager.cpp
@ -1,6 +1,7 @@
 /*
 *  © 2022 Chris Harlow
 *  © 2022 Harald Barth
 *  © 2023 Colin Murdoch
 *  All rights reserved.
 *  
 *  This file is part of DCC++EX
@ -25,25 +26,27 @@
 #include "MotorDriver.h"
 #include "DCCTimer.h"
 #include "DIAG.h"
-#include"CommandDistributor.h"
+#include "CommandDistributor.h"
 #include "DCCEXParser.h"
 // Virtualised Motor shield multi-track hardware Interface
 #define FOR_EACH_TRACK(t) for (byte t=0;t<=lastTrack;t++)
 #define APPLY_BY_MODE(findmode,function) \
        FOR_EACH_TRACK(t) \
-            if (trackMode[t]==findmode) \
+	    if (track[t]->getMode()==findmode)	\
                track[t]->function;
-
+#ifndef DISABLE_PROG
 const int16_t HASH_KEYWORD_PROG = -29718;
 #endif
 const int16_t HASH_KEYWORD_MAIN = 11339;
 const int16_t HASH_KEYWORD_OFF = 22479;  
 const int16_t HASH_KEYWORD_NONE = -26550;
 const int16_t HASH_KEYWORD_DC = 2183;  
 const int16_t HASH_KEYWORD_DCX = 6463; // DC reversed polarity 
 const int16_t HASH_KEYWORD_EXT = 8201; // External DCC signal
 const int16_t HASH_KEYWORD_A = 65; // parser makes single chars the ascii.   
 MotorDriver * TrackManager::track[MAX_TRACKS];
 TRACK_MODE TrackManager::trackMode[MAX_TRACKS];
 int16_t TrackManager::trackDCAddr[MAX_TRACKS];
 POWERMODE TrackManager::mainPowerGuess=POWERMODE::OFF;
@ -52,7 +55,7 @@ bool TrackManager::progTrackSyncMain=false;
 bool TrackManager::progTrackBoosted=false; 
 int16_t TrackManager::joinRelay=UNUSED_PIN;
 #ifdef ARDUINO_ARCH_ESP32
-byte TrackManager::tempProgTrack=MAX_TRACKS+1;
+byte TrackManager::tempProgTrack=MAX_TRACKS+1; // MAX_TRACKS+1 is the unused flag
 #endif
 #ifdef ANALOG_READ_INTERRUPT
@ -73,7 +76,7 @@ void TrackManager::sampleCurrent() {
    waiting = false;
    tr++;
    if (tr > lastTrack) tr = 0;
-    if (lastTrack < 2 || trackMode[tr] & TRACK_MODE_PROG) {
+    if (lastTrack < 2 || track[tr]->getMode() & TRACK_MODE_PROG) {
      return; // We could continue but for prog track we
              // rather do it in next interrupt beacuse
              // that gives us well defined sampling point.
@ -84,7 +87,7 @@ void TrackManager::sampleCurrent() {
  if (!waiting) {
    // look for a valid track to sample or until we are around
    while (true) {
-      if (trackMode[tr] & ( TRACK_MODE_MAIN|TRACK_MODE_PROG|TRACK_MODE_DC|TRACK_MODE_DCX|TRACK_MODE_EXT )) {
+      if (track[tr]->getMode() & ( TRACK_MODE_MAIN|TRACK_MODE_PROG|TRACK_MODE_DC|TRACK_MODE_DCX|TRACK_MODE_EXT )) {
 	track[tr]->startCurrentFromHW();
 	// for scope debug track[1]->setBrake(1);
 	waiting = true;
@ -116,19 +119,31 @@ void TrackManager::Setup(const FSH * shieldname,
    // 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
-  // TODO Fault pin config for odd motor boards (example pololu)
+  // Fault pin config for odd motor boards (example pololu)
-  // MotorDriver::commonFaultPin = ((mainDriver->getFaultPin() == progDriver->getFaultPin())
+  FOR_EACH_TRACK(t) {
-  //				 && (mainDriver->getFaultPin() != UNUSED_PIN));
+    for (byte s=t+1;s<=lastTrack;s++) {
-  DCC::begin(shieldname);   
+      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);
 }
 void TrackManager::addTrack(byte t, MotorDriver* driver) {
     trackMode[t]=TRACK_MODE_OFF;
     track[t]=driver;
     if (driver) {
         track[t]->setPower(POWERMODE::OFF);
         track[t]->setMode(TRACK_MODE_NONE);
 	 track[t]->setTrackLetter('A'+t);
         lastTrack=t;
     } 
@ -140,10 +155,16 @@ void TrackManager::setDCCSignal( bool on) {
  HAVE_PORTA(shadowPORTA=PORTA);
  HAVE_PORTB(shadowPORTB=PORTB);
  HAVE_PORTC(shadowPORTC=PORTC);
  HAVE_PORTD(shadowPORTD=PORTD);
  HAVE_PORTE(shadowPORTE=PORTE);
  HAVE_PORTF(shadowPORTF=PORTF);
  APPLY_BY_MODE(TRACK_MODE_MAIN,setSignal(on));
  HAVE_PORTA(PORTA=shadowPORTA);
  HAVE_PORTB(PORTB=shadowPORTB);
  HAVE_PORTC(PORTC=shadowPORTC);
  HAVE_PORTD(PORTD=shadowPORTD);
  HAVE_PORTE(PORTE=shadowPORTE);
  HAVE_PORTF(PORTF=shadowPORTF);
 }
 void TrackManager::setCutout( bool on) {
@ -158,10 +179,16 @@ void TrackManager::setPROGSignal( bool on) {
  HAVE_PORTA(shadowPORTA=PORTA);
  HAVE_PORTB(shadowPORTB=PORTB);
  HAVE_PORTC(shadowPORTC=PORTC);
  HAVE_PORTD(shadowPORTD=PORTD);
  HAVE_PORTE(shadowPORTE=PORTE);
  HAVE_PORTF(shadowPORTF=PORTF);
  APPLY_BY_MODE(TRACK_MODE_PROG,setSignal(on));
  HAVE_PORTA(PORTA=shadowPORTA);
  HAVE_PORTB(PORTB=shadowPORTB);
  HAVE_PORTC(PORTC=shadowPORTC);
  HAVE_PORTD(PORTD=shadowPORTD);
  HAVE_PORTE(PORTE=shadowPORTE);
  HAVE_PORTF(PORTF=shadowPORTF);
 }
 // setDCSignal(), called from normal context
@ -169,22 +196,27 @@ void TrackManager::setPROGSignal( bool on) {
 // with interrupts turned off around the critical section
 void TrackManager::setDCSignal(int16_t cab, byte speedbyte) {
  FOR_EACH_TRACK(t) {
-    if (trackDCAddr[t]!=cab) continue;
+    if (trackDCAddr[t]!=cab && cab != 0) continue;
-    if (trackMode[t]==TRACK_MODE_DC) track[t]->setDCSignal(speedbyte);
+    if (track[t]->getMode()==TRACK_MODE_DC) track[t]->setDCSignal(speedbyte);
-    else if (trackMode[t]==TRACK_MODE_DCX) track[t]->setDCSignal(speedbyte ^ 128);
+    else if (track[t]->getMode()==TRACK_MODE_DCX) track[t]->setDCSignal(speedbyte ^ 128);
  }
 }    
 bool TrackManager::setTrackMode(byte trackToSet, TRACK_MODE mode, int16_t dcAddr) {
    if (trackToSet>lastTrack || track[trackToSet]==NULL) return false;
-    //DIAG(F("Track=%c"),trackToSet+'A');
+    //DIAG(F("Track=%c Mode=%d"),trackToSet+'A', mode);
    // DC tracks require a motorDriver that can set brake!
-    if ((mode==TRACK_MODE_DC || mode==TRACK_MODE_DCX)
+    if (mode==TRACK_MODE_DC || mode==TRACK_MODE_DCX) {
-         && !track[trackToSet]->brakeCanPWM()) {
+#if defined(ARDUINO_AVR_UNO)
-             DIAG(F("Brake pin can't PWM: No DC"));
+      DIAG(F("Uno has no PWM timers available for DC"));
-             return false; 
+      return false;
-         }
+#endif
      if (!track[trackToSet]->brakeCanPWM()) {
 	DIAG(F("Brake pin can't PWM: No DC"));
 	return false;
      }
    }
 #ifdef ARDUINO_ARCH_ESP32
    // remove pin from MUX matrix and turn it off
@ -198,12 +230,16 @@ bool TrackManager::setTrackMode(byte trackToSet, TRACK_MODE mode, int16_t dcAddr
      pinMode(p.invpin, OUTPUT); // gpio_reset_pin may reset to input
    }
 #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 (trackMode[t]==TRACK_MODE_PROG && t != trackToSet) {
+	if (track[t]->getMode()==TRACK_MODE_PROG && t != trackToSet) {
 	  track[t]->setPower(POWERMODE::OFF);
-	  trackMode[t]=TRACK_MODE_OFF;
+	  track[t]->setMode(TRACK_MODE_NONE);
 	  track[t]->makeProgTrack(false);     // revoke prog track special handling
    streamTrackState(NULL,t);
 	}
@ -211,7 +247,7 @@ bool TrackManager::setTrackMode(byte trackToSet, TRACK_MODE mode, int16_t dcAddr
    } else {
      track[trackToSet]->makeProgTrack(false); // only the prog track knows it's type
    }
-    trackMode[trackToSet]=mode;
+    track[trackToSet]->setMode(mode);
    trackDCAddr[trackToSet]=dcAddr;
    streamTrackState(NULL,trackToSet);
@ -238,7 +274,7 @@ bool TrackManager::setTrackMode(byte trackToSet, TRACK_MODE mode, int16_t dcAddr
      // 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 (trackMode[t]==TRACK_MODE_DC || trackMode[t]==TRACK_MODE_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
@ -246,7 +282,7 @@ bool TrackManager::setTrackMode(byte trackToSet, TRACK_MODE mode, int16_t dcAddr
 	  track[t]->trackPWM=false; // this track sure can not run with PWM
 	  //DIAG(F("Track %c trackPWM 0 (not capable)"), t+'A');
 	}
-      } else if (trackMode[t]==TRACK_MODE_MAIN || trackMode[t]==TRACK_MODE_PROG) {
+      } 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;
@ -284,7 +320,7 @@ bool TrackManager::setTrackMode(byte trackToSet, TRACK_MODE mode, int16_t dcAddr
 void TrackManager::applyDCSpeed(byte t) {
  uint8_t speedByte=DCC::getThrottleSpeedByte(trackDCAddr[t]);
-  if (trackMode[t]==TRACK_MODE_DCX)
+  if (track[t]->getMode()==TRACK_MODE_DCX)
    speedByte = speedByte ^ 128; // reverse direction bit
  track[t]->setDCSignal(speedByte);
 }
@ -296,6 +332,7 @@ bool TrackManager::parseJ(Print *stream, int16_t params, int16_t p[])
        FOR_EACH_TRACK(t)
             streamTrackState(stream,t);
        return true;
    }
    p[0]-=HASH_KEYWORD_A;  // convert A... to 0.... 
@ -306,11 +343,13 @@ bool TrackManager::parseJ(Print *stream, int16_t params, int16_t p[])
    if (params==2  && p[1]==HASH_KEYWORD_MAIN) // <= id MAIN>
        return setTrackMode(p[0],TRACK_MODE_MAIN);
 #ifndef DISABLE_PROG
    if (params==2  && p[1]==HASH_KEYWORD_PROG) // <= id PROG>
        return setTrackMode(p[0],TRACK_MODE_PROG);
 #endif
-    if (params==2  && p[1]==HASH_KEYWORD_OFF) // <= id OFF>
+    if (params==2  && (p[1]==HASH_KEYWORD_OFF || p[1]==HASH_KEYWORD_NONE)) // <= id OFF> <= id NONE>
-        return setTrackMode(p[0],TRACK_MODE_OFF);
+        return setTrackMode(p[0],TRACK_MODE_NONE);
    if (params==2  && p[1]==HASH_KEYWORD_EXT) // <= id EXT>
        return setTrackMode(p[0],TRACK_MODE_EXT);
@ -328,49 +367,57 @@ void TrackManager::streamTrackState(Print* stream, byte t) {
  // null stream means send to commandDistributor for broadcast
  if (track[t]==NULL) return;
  auto format=F("");
-  switch(trackMode[t]) {
+  bool pstate = TrackManager::isPowerOn(t);
  switch(track[t]->getMode()) {
  case TRACK_MODE_MAIN:
-      format=F("<= %c MAIN>\n");
+      if (pstate) {format=F("<= %c MAIN ON>\n");} else {format = F("<= %c MAIN OFF>\n");}
      break;
 #ifndef DISABLE_PROG
  case TRACK_MODE_PROG:
-      format=F("<= %c PROG>\n");
+      if (pstate) {format=F("<= %c PROG ON>\n");} else {format=F("<= %c PROG OFF>\n");}
      break;
-  case TRACK_MODE_OFF:
+#endif
-      format=F("<= %c OFF>\n");
+  case TRACK_MODE_NONE:
      if (pstate) {format=F("<= %c NONE ON>\n");} else {format=F("<= %c NONE OFF>\n");}
      break;
  case TRACK_MODE_EXT:
-      format=F("<= %c EXT>\n");
+      if (pstate) {format=F("<= %c EXT ON>\n");} else {format=F("<= %c EXT OFF>\n");}
      break;
  case TRACK_MODE_DC:
-      format=F("<= %c DC %d>\n");
+      if (pstate) {format=F("<= %c DC %d ON>\n");} else {format=F("<= %c DC %d OFF>\n");}
      break;
  case TRACK_MODE_DCX:
-      format=F("<= %c DCX %d>\n");
+      if (pstate) {format=F("<= %c DCX %d ON>\n");} else {format=F("<= %c DCX %d OFF>\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]);
+  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++;
    if (nextCycleTrack>lastTrack) nextCycleTrack=0;
    if (track[nextCycleTrack]==NULL) return;
    MotorDriver * motorDriver=track[nextCycleTrack];
-    bool useProgLimit=dontLimitProg? false: trackMode[nextCycleTrack]==TRACK_MODE_PROG;
+    bool useProgLimit=dontLimitProg? false: track[nextCycleTrack]->getMode()==TRACK_MODE_PROG;
    motorDriver->checkPowerOverload(useProgLimit, nextCycleTrack);   
 }
 MotorDriver * TrackManager::getProgDriver() {
    FOR_EACH_TRACK(t)
-        if (trackMode[t]==TRACK_MODE_PROG) return track[t];
+      if (track[t]->getMode()==TRACK_MODE_PROG) return track[t];
    return NULL;
 } 
@ -378,54 +425,75 @@ MotorDriver * TrackManager::getProgDriver() {
 std::vector<MotorDriver *>TrackManager::getMainDrivers() {
  std::vector<MotorDriver *>  v;
  FOR_EACH_TRACK(t)
-    if (trackMode[t]==TRACK_MODE_MAIN) v.push_back(track[t]);
+    if (track[t]->getMode()==TRACK_MODE_MAIN) v.push_back(track[t]);
  return v;
 }
 #endif
-void TrackManager::setPower2(bool setProg,POWERMODE mode) {
+void TrackManager::setPower2(bool setProg,bool setJoin, POWERMODE mode) {
    if (!setProg) mainPowerGuess=mode; 
    FOR_EACH_TRACK(t) {
-        MotorDriver * driver=track[t]; 
+
-        if (!driver) continue; 
+      TrackManager::setTrackPower(setProg, setJoin, mode, t);
-        switch (trackMode[t]) {
+      
            case TRACK_MODE_MAIN:
                if (setProg) break; 
                // toggle brake before turning power on - resets overcurrent error
                // on the Pololu board if brake is wired to ^D2.
 		// XXX see if we can make this conditional
                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;  
            case TRACK_MODE_EXT:
 	        driver->setBrake(true);
 	        driver->setBrake(false);
 		driver->setPower(mode);
 	        break;
            case TRACK_MODE_OFF:
                break;
        }
    }
    return;
 }
 void TrackManager::setTrackPower(bool setProg, bool setJoin, POWERMODE mode, byte thistrack) {
      //DIAG(F("SetTrackPower Processing Track %d"), thistrack);
      MotorDriver * driver=track[thistrack]; 
      if (!driver) return; 
      switch (track[thistrack]->getMode()) {
          case TRACK_MODE_MAIN:
              if (setProg) break; 
              // toggle brake before turning power on - resets overcurrent error
              // on the Pololu board if brake is wired to ^D2.
              // XXX see if we can make this conditional
              driver->setBrake(true);
              driver->setBrake(false); // DCC runs with brake off
              driver->setPower(mode);  
              break; 
          case TRACK_MODE_DC:
          case TRACK_MODE_DCX:
              //DIAG(F("Processing track - %d setProg %d"), thistrack, setProg);
              if (setProg || setJoin)  break; 
              driver->setBrake(true); // DC starts with brake on
              applyDCSpeed(thistrack);        // speed match DCC throttles
              driver->setPower(mode);
              break;  
          case TRACK_MODE_PROG:
              if (!setProg && !setJoin) break; 
              driver->setBrake(true);
              driver->setBrake(false);
              driver->setPower(mode);
              break;  
          case TRACK_MODE_EXT:
              driver->setBrake(true);
              driver->setBrake(false);
              driver->setPower(mode);
        break;
          case TRACK_MODE_NONE:
              break;
        }
 }
 void TrackManager::reportPowerChange(Print* stream, byte thistrack) {
  // 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);                  
 }
 POWERMODE TrackManager::getProgPower() {
    FOR_EACH_TRACK(t)
-        if (trackMode[t]==TRACK_MODE_PROG) 
+      if (track[t]->getMode()==TRACK_MODE_PROG) 
-                return track[t]->getPower();
+	  return track[t]->getPower();
    return POWERMODE::OFF;   
  }
@ -469,7 +537,7 @@ void TrackManager::setJoin(bool joined) {
 #ifdef ARDUINO_ARCH_ESP32
  if (joined) {
    FOR_EACH_TRACK(t) {
-      if (trackMode[t]==TRACK_MODE_PROG) {
+      if (track[t]->getMode()==TRACK_MODE_PROG) {
 	tempProgTrack = t;
 	setTrackMode(t, TRACK_MODE_MAIN);
 	break;
@ -477,7 +545,12 @@ void TrackManager::setJoin(bool joined) {
    }
  } else {
    if (tempProgTrack != MAX_TRACKS+1) {
      // 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
      setTrackMode(tempProgTrack, TRACK_MODE_PROG);
      track[tempProgTrack]->setPower(tPTmode);              //set track status as it was before
      tempProgTrack = MAX_TRACKS+1;
    }
  }
@ -485,3 +558,39 @@ void TrackManager::setJoin(bool joined) {
  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;   
  }
 bool TrackManager::isProg(byte t) {
    if (track[t]->getMode()==TRACK_MODE_PROG)
        return true;
    return false;
 }
 byte TrackManager::returnMode(byte t) {
    return (track[t]->getMode());
 }
 int16_t TrackManager::returnDCAddr(byte t) {
    return (trackDCAddr[t]);
 }
 const char* TrackManager::getModeName(byte Mode) {
  //DIAG(F("PowerMode %d"), Mode);
 switch (Mode)
  {
  case 1: return "NONE";
  case 2: return "MAIN";
  case 4: return "PROG";
  case 8: return "DC";
  case 16: return "DCX";
  case 32: return "EXT";
  default: return "----";
  }
 }
--- a/TrackManager.h
+++ b/TrackManager.h
@ -1,6 +1,8 @@
 /*
 *  © 2022 Chris Harlow
 *  © 2022 Harald Barth
 *  © 2023 Colin Murdoch
 * 
 *  All rights reserved.
 *  
 *  This file is part of CommandStation-EX
@ -27,10 +29,6 @@
 #include "MotorDriver.h"
 // Virtualised Motor shield multi-track hardware Interface
 // use powers of two so we can do logical and/or on the track modes in if clauses.
 enum TRACK_MODE : byte {TRACK_MODE_OFF = 1, TRACK_MODE_MAIN = 2, TRACK_MODE_PROG = 4,
                        TRACK_MODE_DC = 8, TRACK_MODE_DCX = 16, TRACK_MODE_EXT = 32};
 // These constants help EXRAIL macros say SET_TRACK(2,mode) OR SET_TRACK(C,mode) etc.
 const byte TRACK_NUMBER_0=0, TRACK_NUMBER_A=0;    
 const byte TRACK_NUMBER_1=1, TRACK_NUMBER_B=1;    
@ -41,6 +39,10 @@ const byte TRACK_NUMBER_5=5, TRACK_NUMBER_F=5;
 const byte TRACK_NUMBER_6=6, TRACK_NUMBER_G=6;    
 const byte TRACK_NUMBER_7=7, TRACK_NUMBER_H=7;    
 // These constants help EXRAIL macros convert Track Power e.g. SET_POWER(A ON|OFF).
 const byte TRACK_POWER_0=0, TRACK_POWER_OFF=0;    
 const byte TRACK_POWER_1=1, TRACK_POWER_ON=1;   
 class TrackManager {
  public:
    static void Setup(const FSH * shieldName,
@ -62,10 +64,14 @@ class TrackManager {
 #ifdef ARDUINO_ARCH_ESP32
  static std::vector<MotorDriver *>getMainDrivers();
 #endif
-    static void setPower2(bool progTrack,POWERMODE mode);
+  
    static void setPower2(bool progTrack,bool joinTrack,POWERMODE mode);
    static void setPower(POWERMODE mode) {setMainPower(mode); setProgPower(mode);}
-    static void setMainPower(POWERMODE mode) {setPower2(false,mode);}
+    static void setMainPower(POWERMODE mode) {setPower2(false,false,mode);}
-    static void setProgPower(POWERMODE mode) {setPower2(true,mode);}
+    static void setProgPower(POWERMODE mode) {setPower2(true,false,mode);}
    static void setJoinPower(POWERMODE mode) {setPower2(false,true,mode);}
    static void setTrackPower(bool setProg, bool setJoin, POWERMODE mode, byte thistrack);
    static const int16_t MAX_TRACKS=8;
    static bool setTrackMode(byte track, TRACK_MODE mode, int16_t DCaddr=0);
@ -79,12 +85,25 @@ class TrackManager {
    static void sampleCurrent();
    static void reportGauges(Print* stream);
    static void reportCurrent(Print* stream);
    static void reportPowerChange(Print* stream, byte thistrack);
    static void reportObsoleteCurrent(Print* stream); 
    static void streamTrackState(Print* stream, byte t);
    static bool isPowerOn(byte t);
    static bool isProg(byte t);
    static byte returnMode(byte t);
    static int16_t returnDCAddr(byte t);
    static const char* getModeName(byte Mode);
    static int16_t joinRelay;
    static bool progTrackSyncMain;  // true when prog track is a siding switched to main
-     static bool progTrackBoosted;   // true when prog track is not current limited
+    static bool progTrackBoosted;   // true when prog track is not current limited
 #ifdef DEBUG_ADC
  public:
 #else
  private:
 #endif
    static MotorDriver* track[MAX_TRACKS];
  private:
    static void addTrack(byte t, MotorDriver* driver);
@ -93,8 +112,6 @@ class TrackManager {
    static POWERMODE mainPowerGuess;
    static void applyDCSpeed(byte t);
    static MotorDriver* track[MAX_TRACKS];
    static TRACK_MODE trackMode[MAX_TRACKS]; 
    static int16_t trackDCAddr[MAX_TRACKS];  // dc address if TRACK_MODE_DC or TRACK_MODE_DCX
 #ifdef ARDUINO_ARCH_ESP32
    static byte tempProgTrack; // holds the prog track number during join
--- a/Turnouts.cpp
+++ b/Turnouts.cpp
@ -250,6 +250,7 @@
      }
    }
    tt = (Turnout *)new ServoTurnout(id, vpin, thrownPosition, closedPosition, profile, closed);
    DIAG(F("Turnout 0x%x size %d size %d"), tt, sizeof(Turnout),sizeof(struct TurnoutData));
    IODevice::writeAnalogue(vpin, closed ? closedPosition : thrownPosition, PCA9685::Instant);
    return tt;
 #else
--- a/Turnouts.h
+++ b/Turnouts.h
@ -69,10 +69,12 @@ protected:
    uint16_t id;
  } _turnoutData;  // 3 bytes
 #ifndef DISABLE_EEPROM
  // Address in eeprom of first byte of the _turnoutData struct (containing the closed flag).
  // Set to zero if the object has not been saved in EEPROM, e.g. for newly created Turnouts, and 
  // for all LCN turnouts.
  uint16_t _eepromAddress = 0;
 #endif
  // Pointer to next turnout on linked list.
  Turnout *_nextTurnout = 0;
--- a/Turntables.cpp
+++ b/Turntables.cpp
@ -0,0 +1,268 @@
 /*
 *  © 2023 Peter Cole
 *  All rights reserved.
 *  
 *  This file is part of CommandStation-EX
 *
 *  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 "defines.h"
 #include <Arduino.h>
 #include "Turntables.h"
 #include "StringFormatter.h"
 #include "CommandDistributor.h"
 #include "EXRAIL2.h"
 #include "DCC.h"
 // No turntable support without HAL
 #ifndef IO_NO_HAL
 /*
 * Protected static data
 */
 Turntable *Turntable::_firstTurntable = 0;
 /*
 * Public static data
 */
 int Turntable::turntablelistHash = 0;
 /*
 * Protected static functions
 */
 // Add new turntable to end of list
 void Turntable::add(Turntable *tto) {
  if (!_firstTurntable) {
    _firstTurntable = tto;
  } else {
    Turntable *ptr = _firstTurntable;
    for ( ; ptr->_nextTurntable!=0; ptr=ptr->_nextTurntable) {}
    ptr->_nextTurntable = tto;
  }
  turntablelistHash++;
 }
 // Add a position
 void Turntable::addPosition(uint8_t idx, uint16_t value, uint16_t angle) {
  _turntablePositions.insert(idx, value, angle);
 }
 // Get value for position
 uint16_t Turntable::getPositionValue(uint8_t position) {
  TurntablePosition* currentPosition = _turntablePositions.getHead();
  while (currentPosition) {
    if (currentPosition->index == position) {
      return currentPosition->data;
    }
    currentPosition = currentPosition->next;
  }
  return false;
 }
 // Get value for position
 uint16_t Turntable::getPositionAngle(uint8_t position) {
  TurntablePosition* currentPosition = _turntablePositions.getHead();
  while (currentPosition) {
    if (currentPosition->index == position) {
      return currentPosition->angle;
    }
    currentPosition = currentPosition->next;
  }
  return false;
 }
 // Get the count of positions associated with the turntable
 uint8_t Turntable::getPositionCount()  {
  TurntablePosition* currentPosition = _turntablePositions.getHead();
  uint8_t count = 0;
  while (currentPosition) {
    count++;
    currentPosition = currentPosition->next;
  }
  return count;
 }
 /*
 * Public static functions
 */
 // Find turntable from list
 Turntable *Turntable::get(uint16_t id) {
  for (Turntable *tto = _firstTurntable; tto != nullptr; tto = tto->_nextTurntable)
    if (tto->_turntableData.id == id) return tto;
  return NULL;
 }
 // Find turntable via Vpin
 Turntable *Turntable::getByVpin(VPIN vpin) {
  for (Turntable *tto = _firstTurntable; tto != nullptr; tto = tto->_nextTurntable) {
    if (tto->isEXTT()) {
      EXTTTurntable *exttTto = static_cast<EXTTTurntable*>(tto);
      if (exttTto->getVpin() == vpin) {
        return tto;
      }
    }
  }
  return nullptr;
 }
 // Get the current position for turntable with the specified ID
 uint8_t Turntable::getPosition(uint16_t id) {
  Turntable *tto = get(id);
  if (!tto) return false;
  return tto->getPosition();
 }
 // Got the moving state of the specified turntable
 bool Turntable::ttMoving(uint16_t id) {
  Turntable *tto = get(id);
  if (!tto) return false;
  return tto->isMoving();
 }
 // Initiate a turntable move
 bool Turntable::setPosition(uint16_t id, uint8_t position, uint8_t activity) {
 #if defined(DIAG_IO)
  DIAG(F("Rotate turntable %d to position %d, activity %d)"), id, position, activity);
 #endif
  Turntable *tto = Turntable::get(id);
  if (!tto) return false;
  if (tto->isMoving()) return false;
  bool ok = tto->setPositionInternal(position, activity);
  if (ok) {
    // We only deal with broadcasts for DCC turntables here, EXTT in the device driver
    if (!tto->isEXTT()) {
      CommandDistributor::broadcastTurntable(id, position, false);
    }
    // Trigger EXRAIL rotateEvent for both types here if changed
 #if defined(EXRAIL_ACTIVE)
    bool rotated = false;
    if (position != tto->_previousPosition) rotated = true;
    RMFT2::rotateEvent(id, rotated);
 #endif
  }
  return ok;
 }
 /*************************************************************************************
 * EXTTTurntable - EX-Turntable device.
 * 
 *************************************************************************************/
 // Private constructor
 EXTTTurntable::EXTTTurntable(uint16_t id, VPIN vpin) :
  Turntable(id, TURNTABLE_EXTT)
 {
  _exttTurntableData.vpin = vpin;
 }
 using DevState = IODevice::DeviceStateEnum;
 // Create function
  Turntable *EXTTTurntable::create(uint16_t id, VPIN vpin) {
 #ifndef IO_NO_HAL
    Turntable *tto = get(id);
    if (tto) {
      if (tto->isType(TURNTABLE_EXTT)) {
        EXTTTurntable *extt = (EXTTTurntable *)tto;
        extt->_exttTurntableData.vpin = vpin;
        return tto;
      }
    }
    if (!IODevice::exists(vpin)) return nullptr;
    if (IODevice::getStatus(vpin) == DevState::DEVSTATE_FAILED) return nullptr;
    if (Turntable::getByVpin(vpin)) return nullptr;
    tto = (Turntable *)new EXTTTurntable(id, vpin);
    DIAG(F("Turntable 0x%x size %d size %d"), tto, sizeof(Turntable), sizeof(struct TurntableData));
    return tto;
 #else
  (void)id;
  (void)vpin;
  return NULL;
 #endif
  }
  void EXTTTurntable::print(Print *stream) {
    StringFormatter::send(stream, F("<i %d EXTURNTABLE %d>\n"), _turntableData.id, _exttTurntableData.vpin);
  }
  // EX-Turntable specific code for moving to the specified position
  bool EXTTTurntable::setPositionInternal(uint8_t position, uint8_t activity) {
 #ifndef IO_NO_HAL
    int16_t value;
    if (position == 0) {
      value = 0;  // Position 0 is just to send activities
    } else {
      if (activity > 1) return false; // If sending a position update, only phase changes valid (0|1)
      value = getPositionValue(position); // Get position value from position list
    }
    if (position > 0 && !value) return false; // Return false if it's not a valid position
    // Set position via device driver
    _previousPosition = _turntableData.position;
    _turntableData.position = position;
    EXTurntable::writeAnalogue(_exttTurntableData.vpin, value, activity);
 #else
    (void)position;
 #endif
    return true;
  }
 /*************************************************************************************
 * DCCTurntable - DCC Turntable device.
 * 
 *************************************************************************************/
 // Private constructor
 DCCTurntable::DCCTurntable(uint16_t id) : Turntable(id, TURNTABLE_DCC) {}
 // Create function
  Turntable *DCCTurntable::create(uint16_t id) {
 #ifndef IO_NO_HAL
    Turntable *tto = get(id);
    if (!tto) {
      tto = (Turntable *)new DCCTurntable(id);
      DIAG(F("Turntable 0x%x size %d size %d"), tto, sizeof(Turntable), sizeof(struct TurntableData));
    }
    return tto;
 #else
  (void)id;
  return NULL;
 #endif
  }
  void DCCTurntable::print(Print *stream) {
    StringFormatter::send(stream, F("<i %d DCCTURNTABLE>\n"), _turntableData.id);
  }
  // EX-Turntable specific code for moving to the specified position
  bool DCCTurntable::setPositionInternal(uint8_t position, uint8_t activity) {
 #ifndef IO_NO_HAL
    int16_t value = getPositionValue(position);
    if (position == 0 || !value) return false; // Return false if it's not a valid position
    // Set position via device driver
    int16_t addr=value>>3;
    int16_t subaddr=(value>>1) & 0x03;
    bool active=value & 0x01;
    _previousPosition = _turntableData.position;
    _turntableData.position = position;
    DCC::setAccessory(addr, subaddr, active);
 #else
    (void)position;
 #endif
    return true;
  }
 #endif
--- a/Turntables.h
+++ b/Turntables.h
@ -0,0 +1,243 @@
 /*
 *  © 2023 Peter Cole
 *  All rights reserved.
 *  
 *  This file is part of CommandStation-EX
 *
 *  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/>.
 */
 #ifndef TURNTABLES_H
 #define TURNTABLES_H
 #include <Arduino.h>
 #include "IODevice.h"
 #include "StringFormatter.h"
 // No turntable support without HAL
 #ifndef IO_NO_HAL
 // Turntable type definitions
 // EXTT = EX-Turntable
 // DCC = DCC accessory turntables - to be added later
 enum {
  TURNTABLE_EXTT = 0,
  TURNTABLE_DCC = 1,
 };
 /*************************************************************************************
 * Turntable positions.
 * 
 *************************************************************************************/
 struct TurntablePosition {
  uint8_t index;
  uint16_t data;
  uint16_t angle;
  TurntablePosition* next;
  TurntablePosition(uint8_t idx, uint16_t value, uint16_t angle) : index(idx), data(value), angle(angle), next(nullptr) {}
 };
 class TurntablePositionList {
 public:
  TurntablePositionList() : head(nullptr) {}
  void insert(uint8_t idx, uint16_t value, uint16_t angle) {
    TurntablePosition* newPosition = new TurntablePosition(idx, value, angle);
    if(!head) {
      head = newPosition;
    } else {
      newPosition->next = head;
      head = newPosition;
    }
  }
  TurntablePosition* getHead() {
    return head;
  }
 private:
  TurntablePosition* head;
 };
 /*************************************************************************************
 * Turntable - Base class for turntables.
 * 
 *************************************************************************************/
 class Turntable {
 protected:
  /*
   * Object data
   */
  //  Data common to all turntable types
  struct TurntableData {
    union {
      struct {
        bool hidden : 1;
        bool turntableType : 1;
        uint8_t position : 6;       // Allows up to 63 positions including 0/home
      };
      uint8_t flags;
    };
    uint16_t id;
  } _turntableData;
  // Pointer to next turntable object
  Turntable *_nextTurntable = 0;
  // Linked list for positions
  TurntablePositionList _turntablePositions;
  // Store the previous position to allow checking for changes
  uint8_t _previousPosition = 0;
  // Store the current state of the turntable
  bool _isMoving = false;
  /*
   * Constructor
   */
  Turntable(uint16_t id, uint8_t turntableType) {
    _turntableData.id = id;
    _turntableData.turntableType = turntableType;
    _turntableData.hidden = false;
    _turntableData.position = 0;
    add(this);
  }
  /*
   * Static data
   */
  static Turntable *_firstTurntable;
  static int _turntablelistHash;
  /*
   * Virtual functions
   */
  virtual bool setPositionInternal(uint8_t position, uint8_t activity) = 0;
  /*
   * Static functions
   */
  static void add(Turntable *tto);
 public:
  static Turntable *get(uint16_t id);
  static Turntable *getByVpin(VPIN vpin);
  /*
   * Static data
   */
  static int turntablelistHash;
  /*
   * Public base class functions
   */
  inline uint8_t getPosition() { return _turntableData.position; }
  inline bool isHidden() { return _turntableData.hidden; }
  inline void setHidden(bool h) {_turntableData.hidden=h; }
  inline bool isType(uint8_t type) { return _turntableData.turntableType == type; }
  inline bool isEXTT() const { return _turntableData.turntableType == TURNTABLE_EXTT; }
  inline uint16_t getId() { return _turntableData.id; }
  inline Turntable *next() { return _nextTurntable; }
  void printState(Print *stream);
  void addPosition(uint8_t idx, uint16_t value, uint16_t angle);
  uint16_t getPositionValue(uint8_t position);
  uint16_t getPositionAngle(uint8_t position);
  uint8_t getPositionCount();
  bool isMoving() { return _isMoving; }
  void setMoving(bool moving) { _isMoving=moving; }
  /*
   * Virtual functions
   */
  virtual void print(Print *stream) {
    (void)stream; // suppress compiler warnings
  }
  virtual ~Turntable() {} // Destructor
  /*
   * Public static functions
   */
  inline static bool exists(uint16_t id) { return get(id) != 0; }
  static bool setPosition(uint16_t id, uint8_t position, uint8_t activity=0);
  static uint8_t getPosition(uint16_t id);
  static bool ttMoving(uint16_t id);
  inline static Turntable *first() { return _firstTurntable; }
  static bool printAll(Print *stream) {
    bool gotOne = false;
    for (Turntable *tto = _firstTurntable; tto != 0; tto = tto->_nextTurntable)
      if (!tto->isHidden()) {
        gotOne = true;
        StringFormatter::send(stream, F("<I %d %d>\n"), tto->getId(), tto->getPosition());
      }
    return gotOne;
  }
 };
 /*************************************************************************************
 * EXTTTurntable - EX-Turntable device.
 * 
 *************************************************************************************/
 class EXTTTurntable : public Turntable {
 private:
  // EXTTTurntableData contains device specific data
  struct EXTTTurntableData {
    VPIN vpin;
  } _exttTurntableData;
  // Constructor
  EXTTTurntable(uint16_t id, VPIN vpin);
 public:
  // Create function
  static Turntable *create(uint16_t id, VPIN vpin);
  void print(Print *stream) override;
  VPIN getVpin() const { return _exttTurntableData.vpin; }
 protected:
  // EX-Turntable specific code for setting position
  bool setPositionInternal(uint8_t position, uint8_t activity) override;
 };
 /*************************************************************************************
 * DCCTurntable - DCC accessory Turntable device.
 * 
 *************************************************************************************/
 class DCCTurntable : public Turntable {
 private:
  // Constructor
  DCCTurntable(uint16_t id);
 public:
  // Create function
  static Turntable *create(uint16_t id);
  void print(Print *stream) override;
 protected:
  // DCC specific code for setting position
  bool setPositionInternal(uint8_t position, uint8_t activity=0) override;
 };
 #endif
 #endif
--- a/WiThrottle.cpp
+++ b/WiThrottle.cpp
@ -235,6 +235,10 @@ int WiThrottle::getLocoId(byte * cmd) {
 void WiThrottle::multithrottle(RingStream * stream, byte * cmd){ 
  char throttleChar=cmd[1];
  int locoid=getLocoId(cmd+3); // -1 for *
  if (locoid > 10239 || locoid < -1) {
    StringFormatter::send(stream, F("No valid DCC loco %d\n"), locoid);
    return;
  }
  byte * aval=cmd;
  while(*aval !=';' && *aval !='\0') aval++;
  if (*aval) aval+=2;  // skip ;>
@ -527,10 +531,13 @@ void WiThrottle::sendRoster(Print* stream) {
  rosterSent=true;
 #ifdef EXRAIL_ACTIVE
  StringFormatter::send(stream,F("RL%d"), RMFT2::rosterNameCount);
-  for (int16_t r=0;r<RMFT2::rosterNameCount;r++) {
+  for (int16_t r=0;;r++) {
      int16_t cabid=GETHIGHFLASHW(RMFT2::rosterIdList,r*2);
-      StringFormatter::send(stream,F("]\\[%S}|{%d}|{%c"),
+      if (cabid == INT16_MAX)
-      RMFT2::getRosterName(cabid),cabid,cabid<128?'S':'L');
+	break;
      if (cabid > 0)
 	StringFormatter::send(stream,F("]\\[%S}|{%d}|{%c"),
 			      RMFT2::getRosterName(cabid),cabid,cabid<128?'S':'L');
  }
  StringFormatter::send(stream,F("\n"));       
 #else
@ -544,14 +551,14 @@ void WiThrottle::sendRoutes(Print* stream) {
    // first pass automations
    for (int ix=0;;ix+=2) {
        int16_t id =GETHIGHFLASHW(RMFT2::automationIdList,ix);
-        if (id==0) break;
+        if (id==INT16_MAX) break;
        const FSH * desc=RMFT2::getRouteDescription(id);
        StringFormatter::send(stream,F("]\\[A%d}|{%S}|{4"),id,desc);
    }
    // second pass routes.
    for (int ix=0;;ix+=2) {
        int16_t id=GETHIGHFLASHW(RMFT2::routeIdList,ix);
-        if (id==0) break;
+        if (id==INT16_MAX) break;
        const FSH * desc=RMFT2::getRouteDescription(id);
        StringFormatter::send(stream,F("]\\[R%d}|{%S}|{2"),id,desc);
    }
@ -567,9 +574,13 @@ void WiThrottle::sendFunctions(Print* stream, byte loco) {
 	myLocos[loco].functionToggles=1<<2; // F2 (HORN)  is a non-toggle
 #ifdef EXRAIL_ACTIVE
-	const char * functionNames=(char *) RMFT2::getRosterFunctions(locoid);
+	const FSH * functionNames= RMFT2::getRosterFunctions(locoid);
-	if (!functionNames) {
+	if (functionNames == NULL) {
-	  // no roster, use non-exrail presets as above 
+	  // no roster entry for locoid, try to find default entry
 	  functionNames= RMFT2::getRosterFunctions(0);
 	}
 	if (functionNames == NULL) {
 	  // no default roster entry either, use non-exrail presets as above 
 	}
 	else if (GETFLASH(functionNames)=='\0') {
 	  // "" = Roster but no functions given
@ -584,7 +595,7 @@ void WiThrottle::sendFunctions(Print* stream, byte loco) {
 	  fkeys=0;
 	  bool firstchar=true;
 	  for (int fx=0;;fx++) {
-	    char c=GETFLASH(functionNames+fx);
+	    char c=GETFLASH((char *)functionNames+fx);
 	    if (c=='\0') {
 	      fkeys++;
 	      break;
--- a/WifiESP32.cpp
+++ b/WifiESP32.cpp
@ -1,5 +1,7 @@
 /*
-    © 2021, Harald Barth.
+    © 2023 Paul M. Antoine
    © 2021 Harald Barth
    © 2023 Nathan Kellenicki
    This file is part of CommandStation-EX
@ -20,6 +22,7 @@
 #if defined(ARDUINO_ARCH_ESP32)
 #include <vector>
 #include "defines.h"
 #include "ESPmDNS.h"
 #include <WiFi.h>
 #include "esp_wifi.h"
 #include "WifiESP32.h"
@ -105,11 +108,18 @@ void wifiLoop(void *){
 }
 #endif
 char asciitolower(char in) {
  if (in <= 'Z' && in >= 'A')
    return in - ('Z' - 'z');
  return in;
 }
 bool WifiESP::setup(const char *SSid,
                    const char *password,
                    const char *hostname,
                    int port,
-                    const byte channel) {
+                    const byte channel,
                    const bool forceAP) {
  bool havePassword = true;
  bool haveSSID = true;
  bool wifiUp = false;
@ -137,7 +147,8 @@ bool WifiESP::setup(const char *SSid,
  if (strncmp(yourNetwork, password, 13) == 0 || strncmp("", password, 13) == 0)
    havePassword = false;
-  if (haveSSID && havePassword) {
+  if (haveSSID && havePassword && !forceAP) {
    WiFi.setHostname(hostname); // Strangely does not work unless we do it HERE!
    WiFi.mode(WIFI_STA);
 #ifdef SERIAL_BT_COMMANDS
    WiFi.setSleep(true);
@ -174,16 +185,20 @@ bool WifiESP::setup(const char *SSid,
      }
    }
  }
-  if (!haveSSID) {
+  if (!haveSSID || forceAP) {
    // prepare all strings
-    String strSSID("DCC_");
+    String strSSID(forceAP ? SSid : "DCCEX_");
-    String strPass("PASS_");
+    String strPass(forceAP ? password : "PASS_");
-    String strMac = WiFi.macAddress();
+    if (!forceAP) {
-    strMac.remove(0,9);
+      String strMac = WiFi.macAddress();
-    strMac.replace(":","");
+      strMac.remove(0,9);
-    strMac.replace(":","");
+      strMac.replace(":","");
-    strSSID.concat(strMac);
+      strMac.replace(":","");
-    strPass.concat(strMac);
+      // convert mac addr hex chars to lower case to be compatible with AT software
      std::transform(strMac.begin(), strMac.end(), strMac.begin(), asciitolower);
      strSSID.concat(strMac);
      strPass.concat(strMac);
    }
    WiFi.mode(WIFI_AP);
 #ifdef SERIAL_BT_COMMANDS
@ -209,6 +224,15 @@ bool WifiESP::setup(const char *SSid,
    // no idea to go on
    return false;
  }
  // Now Wifi is up, register the mDNS service
  if(!MDNS.begin(hostname)) {
    DIAG(F("Wifi setup failed to start mDNS"));
  }
  if(!MDNS.addService("withrottle", "tcp", 2560)) {
    DIAG(F("Wifi setup failed to add withrottle service to mDNS"));
  }
  server = new WiFiServer(port); // start listening on tcp port
  server->begin();
  // server started here
--- a/WifiESP32.h
+++ b/WifiESP32.h
@ -1,5 +1,6 @@
 /*
- *  © 2021, Harald Barth.
+ *  © 2021 Harald Barth
 *  © 2023 Nathan Kellenicki
 *
 *  This file is part of CommandStation-EX
 *
@ -31,7 +32,8 @@ public:
 		    const char *wifiPassword,
 		    const char *hostname,
 		    const int port,
-		    const byte channel);
+		    const byte channel,
 			const bool forceAP);
  static void loop();
 private:
 };
--- a/WifiInterface.cpp
+++ b/WifiInterface.cpp
@ -2,6 +2,7 @@
 *  © 2021 Fred Decker
 *  © 2020-2022 Harald Barth
 *  © 2020-2022 Chris Harlow
 *  © 2023 Nathan Kellenicki
 *  All rights reserved.
 *
 *  This file is part of CommandStation-EX
@ -52,10 +53,32 @@ Stream * WifiInterface::wifiStream;
 #if (defined(ARDUINO_AVR_MEGA) || defined(ARDUINO_AVR_MEGA2560))
 #define NUM_SERIAL 3
 #define SERIAL1 Serial1
 #define SERIAL3 Serial3
 #endif
 #if defined(ARDUINO_ARCH_STM32)
 // Handle serial ports availability on STM32 for variants!
 // #undef NUM_SERIAL
 #if defined(ARDUINO_NUCLEO_F401RE) || defined(ARDUINO_NUCLEO_F411RE)
 #define NUM_SERIAL 3
 #define SERIAL1 Serial1
 #define SERIAL3 Serial6
 #elif defined(ARDUINO_NUCLEO_F446RE)
 #define NUM_SERIAL 3
 #define SERIAL1 Serial3
 #define SERIAL3 Serial5
 #elif defined(ARDUINO_NUCLEO_F413ZH) || defined(ARDUINO_NUCLEO_F429ZI) || defined(ARDUINO_NUCLEO_F446ZE) || defined(ARDUINO_NUCLEO_F412ZG)
 #define NUM_SERIAL 2
 #define SERIAL1 Serial6
 #else
 #warning This variant of Nucleo not yet explicitly supported
 #endif
 #endif
 #ifndef NUM_SERIAL
 #define NUM_SERIAL 1
 #define SERIAL1 Serial1
 #endif
 bool WifiInterface::setup(long serial_link_speed, 
@ -63,7 +86,8 @@ bool WifiInterface::setup(long serial_link_speed,
                          const FSH *wifiPassword,
                          const FSH *hostname,
                          const int port,
-                          const byte channel) {
+                          const byte channel,
                          const bool forceAP) {
  wifiSerialState wifiUp = WIFI_NOAT;
@ -75,27 +99,34 @@ bool WifiInterface::setup(long serial_link_speed,
  (void) hostname;
  (void) port;
  (void) channel;
  (void) forceAP;
 #endif  
 // See if the WiFi is attached to the first serial port
 #if NUM_SERIAL > 0 && !defined(SERIAL1_COMMANDS)
-  Serial1.begin(serial_link_speed);
+  SERIAL1.begin(serial_link_speed);
-  wifiUp = setup(Serial1, wifiESSID, wifiPassword, hostname, port, channel);
+  wifiUp = setup(SERIAL1, wifiESSID, wifiPassword, hostname, port, channel, forceAP);
 #endif
 // Other serials are tried, depending on hardware.
 // Currently only the Arduino Mega 2560 has usable Serial2 (Nucleo-64 boards use Serial 2 for console!)
 #if defined(ARDUINO_AVR_MEGA2560)
 #if NUM_SERIAL > 1 && !defined(SERIAL2_COMMANDS)
  if (wifiUp == WIFI_NOAT)
  {
    Serial2.begin(serial_link_speed);
-    wifiUp = setup(Serial2, wifiESSID, wifiPassword, hostname, port, channel);
+    wifiUp = setup(Serial2, wifiESSID, wifiPassword, hostname, port, channel, forceAP);
  }
 #endif
 #endif
 // We guess here that in all architctures that have a Serial3
 // we can use it for our purpose.
 #if NUM_SERIAL > 2 && !defined(SERIAL3_COMMANDS)
  if (wifiUp == WIFI_NOAT)
  {
-    Serial3.begin(serial_link_speed);
+    SERIAL3.begin(serial_link_speed);
-    wifiUp = setup(Serial3, wifiESSID, wifiPassword, hostname, port, channel);
+    wifiUp = setup(SERIAL3, wifiESSID, wifiPassword, hostname, port, channel, forceAP);
  }
 #endif
@ -113,7 +144,7 @@ bool WifiInterface::setup(long serial_link_speed,
 }
 wifiSerialState WifiInterface::setup(Stream & setupStream,  const FSH* SSid, const FSH* password,
-				     const FSH* hostname,  int port, byte channel) {
+				     const FSH* hostname,  int port, byte channel, bool forceAP) {
  wifiSerialState wifiState;
  static uint8_t ntry = 0;
  ntry++;
@ -122,7 +153,7 @@ wifiSerialState WifiInterface::setup(Stream & setupStream,  const FSH* SSid, con
  DIAG(F("++ Wifi Setup Try %d ++"), ntry);
-  wifiState = setup2( SSid, password, hostname,  port, channel);
+  wifiState = setup2( SSid, password, hostname,  port, channel, forceAP);
  if (wifiState == WIFI_NOAT) {
    LCD(4, F("WiFi no AT chip"));
@ -146,7 +177,7 @@ wifiSerialState WifiInterface::setup(Stream & setupStream,  const FSH* SSid, con
 #pragma GCC diagnostic ignored "-Wunused-parameter"
 #endif
 wifiSerialState WifiInterface::setup2(const FSH* SSid, const FSH* password,
-				      const FSH* hostname, int port, byte channel) {
+				      const FSH* hostname, int port, byte channel, bool forceAP) {
  bool ipOK = false;
  bool oldCmd = false;
@ -169,7 +200,21 @@ wifiSerialState WifiInterface::setup2(const FSH* SSid, const FSH* password,
  // Display the AT version information
  StringFormatter::send(wifiStream, F("AT+GMR\r\n")); 
-  checkForOK(2000, true, false);      // Makes this visible on the console
+  if (checkForOK(2000, F("AT version:"), true, false)) {
    char version[] = "0.0.0.0";
    for (int i=0; i<8;i++) {
      while(!wifiStream->available());
      version[i]=wifiStream->read();
      StringFormatter::printEscape(version[i]);
      if ((version[0] == '0') ||
 	  (version[0] == '2' && version[2] == '0') ||
 	  (version[0] == '2' && version[2] == '2' && version[4] == '0' && version[6] == '0')) {
 	SSid = F("DCCEX_SAYS_BROKEN_FIRMWARE");
 	forceAP = true;
      }
    }
  }
  checkForOK(2000, true, false);
 #ifdef DONT_TOUCH_WIFI_CONF
  DIAG(F("DONT_TOUCH_WIFI_CONF was set: Using existing config"));
@ -199,7 +244,7 @@ wifiSerialState WifiInterface::setup2(const FSH* SSid, const FSH* password,
 	  if (!checkForOK(1000, F("0.0.0.0"), true,false))
 	      ipOK = true;
    }
-  } else {
+  } else if (!forceAP) {
      // SSID was configured, so we assume station (client) mode.
      if (oldCmd) {
 	      // AT command early version supports CWJAP/CWSAP
@ -259,14 +304,19 @@ wifiSerialState WifiInterface::setup2(const FSH* SSid, const FSH* password,
    i=0;
    do {
-      if (STRNCMP_P(yourNetwork, (const char*)password, 13) == 0) {
+      if (!forceAP) {
-	// unconfigured
+        if (STRNCMP_P(yourNetwork, (const char*)password, 13) == 0) {
-        StringFormatter::send(wifiStream, F("AT+CWSAP%s=\"DCCEX_%s\",\"PASS_%s\",%d,4\r\n"),
+    // unconfigured
-                                          oldCmd ? "" : "_CUR", macTail, macTail, channel);
+          StringFormatter::send(wifiStream, F("AT+CWSAP%s=\"DCCEX_%s\",\"PASS_%s\",%d,4\r\n"),
                                            oldCmd ? "" : "_CUR", macTail, macTail, channel);
        } else {
          // password configured by user
          StringFormatter::send(wifiStream, F("AT+CWSAP%s=\"DCCEX_%s\",\"%S\",%d,4\r\n"), oldCmd ? "" : "_CUR",
                                          macTail, password, channel);
        }
      } else {
-        // password configured by user
+        StringFormatter::send(wifiStream, F("AT+CWSAP%s=\"%S\",\"%S\",%d,4\r\n"),
-       StringFormatter::send(wifiStream, F("AT+CWSAP%s=\"DCCEX_%s\",\"%S\",%d,4\r\n"), oldCmd ? "" : "_CUR",
+                                        oldCmd ? "" : "_CUR", SSid, password, channel);
 	                                       macTail, password, channel);
      }
    } while (!checkForOK(WIFI_CONNECT_TIMEOUT, true) && i++<2); // do twice if necessary but ignore failure as AP mode may still be ok
    if (i >= 2)
--- a/WifiInterface.h
+++ b/WifiInterface.h
@ -1,6 +1,7 @@
 /*
 *  © 2020-2021 Chris Harlow
 *  © 2020, Harald Barth.
 *  © 2023 Nathan Kellenicki
 *  All rights reserved.
 *
 *  This file is part of CommandStation-EX
@ -36,17 +37,18 @@ public:
                          const FSH *wifiPassword,
                          const FSH *hostname,
                          const int port,
-                          const byte channel);
+                          const byte channel,
                          const bool forceAP);
  static void loop();
  static void ATCommand(HardwareSerial * stream,const byte *command);
 private:
  static wifiSerialState setup(Stream &setupStream, const FSH *SSSid, const FSH *password,
-                    const FSH *hostname, int port, byte channel);
+                    const FSH *hostname, int port, byte channel, bool forceAP);
  static Stream *wifiStream;
  static DCCEXParser parser;
  static wifiSerialState setup2(const FSH *SSSid, const FSH *password,
-                     const FSH *hostname, int port, byte channel);
+                     const FSH *hostname, int port, byte channel, bool forceAP);
  static bool checkForOK(const unsigned int timeout, bool echo, bool escapeEcho = true);
  static bool checkForOK(const unsigned int timeout, const FSH *waitfor, bool echo, bool escapeEcho = true);
  static bool connected;
--- a/config.example.h
+++ b/config.example.h
@ -1,9 +1,10 @@
 /*
 *  © 2022 Paul M. Antoine
 *  © 2021 Neil McKechnie
- *  © 2020-2021 Harald Barth
+ *  © 2020-2023 Harald Barth
 *  © 2020-2021 Fred Decker
 *  © 2020-2021 Chris Harlow
 *  © 2023 Nathan Kellenicki
 *  
 *  This file is part of CommandStation-EX
 *
@ -27,6 +28,16 @@ The configuration file for DCC-EX Command Station
 **********************************************************************/
 /////////////////////////////////////////////////////////////////////////////////////
 // If you want to add your own motor driver definition(s), add them here
 //   For example MY_SHIELD with display name "MINE":
 //   (remove comment start and end marker if you want to edit and use that)
 /* 
 #define MY_SHIELD F("MINE"), \
 new MotorDriver( 3, 12, UNUSED_PIN, 9, A0, 5.08, 3000, A4), \
 new MotorDriver(11, 13, UNUSED_PIN, 8, A1, 5.08, 1500, A5)
 */
 /////////////////////////////////////////////////////////////////////////////////////
 //  NOTE: Before connecting these boards and selecting one in this software
 //        check the quick install guides!!! Some of these boards require a voltage
@ -34,19 +45,34 @@ The configuration file for DCC-EX Command Station
 //        the correct resistor could damage the sense pin on your Arduino or destroy
 //        the device.
 //
-// DEFINE MOTOR_SHIELD_TYPE BELOW ACCORDING TO THE FOLLOWING TABLE:
+// DEFINE MOTOR_SHIELD_TYPE BELOW. THESE ARE EXAMPLES. FULL LIST IN MotorDrivers.h
 //
 //  STANDARD_MOTOR_SHIELD : Arduino Motor shield Rev3 based on the L298 with 18V 2A per channel
 //  POLOLU_MOTOR_SHIELD   : Pololu MC33926 Motor Driver (not recommended for prog track)
 //  POLOLU_TB9051FTG      : Pololu Dual TB9051FTG Motor Driver
 //  FUNDUMOTO_SHIELD      : Fundumoto Shield, no current sensing (not recommended, no short protection)
 //  FIREBOX_MK1           : The Firebox MK1                    
 //  FIREBOX_MK1S          : The Firebox MK1S
 //  IBT_2_WITH_ARDUINO    : Arduino Motor Shield for PROG and IBT-2 for MAIN
 //  EX8874_SHIELD         : DCC-EX TI DRV8874 based motor shield
 //   |
 //   +-----------------------v
 //
 #define MOTOR_SHIELD_TYPE STANDARD_MOTOR_SHIELD
 //
 /////////////////////////////////////////////////////////////////////////////////////
 //
 // If you want to restrict the maximum current LOWER than what your
 // motor shield can provide, you can do that here. For example if you
 // have a motor shield that can provide 5A and your power supply can
 // only provide 2.5A then you should restict the maximum current to
 // 2.25A (90% of 2.5A) so that DCC-EX does shut off the track before
 // your PS does shut DCC-EX. MAX_CURRENT is in mA so for this example
 // it would be 2250, adjust the number according to your PS. If your
 // PS has a higher rating than your motor shield you do not need this.
 // You can use this as well if you are cautious and your trains do not
 // need full current.
 // #define MAX_CURRENT 2250
 //
 /////////////////////////////////////////////////////////////////////////////////////
 //
 // The IP port to talk to a WIFI or Ethernet shield.
@ -98,6 +124,11 @@ The configuration file for DCC-EX Command Station
 // this line exists or not. If you need to use an alternate channel (we recommend
 // using only 1,6, or 11) you may change it here.
 #define WIFI_CHANNEL 1
 //
 // WIFI_FORCE_AP: If you'd like to specify your own WIFI_SSID in AP mode, set this
 // true. Otherwise it is assumed that you'd like to connect to an existing network
 // with that SSID.
 #define WIFI_FORCE_AP false
 /////////////////////////////////////////////////////////////////////////////////////
 //
@ -128,7 +159,7 @@ The configuration file for DCC-EX Command Station
 //OR define OLED_DRIVER width,height[,address] in pixels (address auto detected if not supplied)
 // 128x32 or 128x64 I2C SSD1306-based devices are supported.
 // Use 132,64 for a SH1106-based I2C device with a 128x64 display.
-// #define OLED_DRIVER 128,32,0x3c
+// #define OLED_DRIVER 0x3c,128,32
 // Define scroll mode as 0, 1 or 2
 //  *  #define SCROLLMODE 0 is scroll continuous (fill screen if poss),
@ -141,7 +172,7 @@ The configuration file for DCC-EX Command Station
 //
 // If you do not need the EEPROM at all, you can disable all the code that saves
 // data in the EEPROM. You might want to do that if you are in a Arduino UNO
-// and want to use the EX-RAIL automation. Otherwise you do not have enough RAM
+// and want to use the EXRAIL automation. Otherwise you do not have enough RAM
 // to do that. Of course, then none of the EEPROM related commands work.
 //
 // EEPROM does not work on ESP32. So on ESP32, EEPROM will always be disabled,
@ -149,6 +180,17 @@ The configuration file for DCC-EX Command Station
 //
 // #define DISABLE_EEPROM
 /////////////////////////////////////////////////////////////////////////////////////
 // DISABLE PROG
 //
 // If you do not need programming capability, you can disable all programming related
 // commands. You might want to do that if you are using an Arduino UNO and still want
 // to use EXRAIL automation, as the Uno is lacking in RAM and Flash to run both.
 // 
 // Note this disables all programming functionality, including EXRAIL.
 //
 // #define DISABLE_PROG
 /////////////////////////////////////////////////////////////////////////////////////
 // REDEFINE WHERE SHORT/LONG ADDR break is. According to NMRA the last short address
 // is 127 and the first long address is 128. There are manufacturers which have
@ -224,5 +266,15 @@ The configuration file for DCC-EX Command Station
 //
 //#define SERIAL_BT_COMMANDS
 // SABERTOOTH
 //
 // This is a very special option and only useful if you happen to have a
 // sabertooth motor controller from dimension engineering configured to
 // take commands from and ESP32 via serial at 9600 baud from GPIO17 (TX)
 // and GPIO16 (RX, currently unused).
 // The number defined is the DCC address for which speed controls are sent
 // to the sabertooth controller _as_well_. Default: Undefined.
 //
 //#define SABERTOOTH 1
 /////////////////////////////////////////////////////////////////////////////////////
--- a/config.h.txt
+++ b/config.h.txt
@ -1,169 +0,0 @@
 /**********************************************************************
 Config.h
 COPYRIGHT (c) 2013-2016 Gregg E. Berman
 COPYRIGHT (c) 2020 Fred Decker
 The configuration file for DCC++ EX Command Station
 **********************************************************************/
 /////////////////////////////////////////////////////////////////////////////////////
 //  NOTE: Before connecting these boards and selecting one in this software
 //        check the quick install guides!!! Some of these boards require a voltage
 //        generating resitor on the current sense pin of the device. Failure to select
 //        the correct resistor could damage the sense pin on your Arduino or destroy
 //        the device.
 //
 // DEFINE MOTOR_SHIELD_TYPE BELOW ACCORDING TO THE FOLLOWING TABLE:
 //
 //  STANDARD_MOTOR_SHIELD : Arduino Motor shield Rev3 based on the L298 with 18V 2A per channel
 //  POLOLU_MOTOR_SHIELD   : Pololu MC33926 Motor Driver (not recommended for prog track)
 //  FUNDUMOTO_SHIELD      : Fundumoto Shield, no current sensing (not recommended, no short protection)
 //  FIREBOX_MK1           : The Firebox MK1                    
 //  FIREBOX_MK1S          : The Firebox MK1S    
 //   |
 //   +-----------------------v
 //
 // #define STANDARD_MOTOR_SHIELD F("STANDARD_MOTOR_SHIELD"),                                              
 //                               new MotorDriver(3, 12, UNUSED_PIN, 9, A0, 0.488, 1500, UNUSED_PIN),
 //                               new MotorDriver(11, 13, UNUSED_PIN, 8, A1, 0.488, 1500, UNUSED_PIN)
 #define MOTOR_SHIELD_TYPE STANDARD_MOTOR_SHIELD
 /////////////////////////////////////////////////////////////////////////////////////
 //
 // The IP port to talk to a WIFI or Ethernet shield.
 //
 #define IP_PORT 2560
 /////////////////////////////////////////////////////////////////////////////////////
 //
 // NOTE: Only supported on Arduino Mega
 // Set to false if you not even want it on the Arduino Mega
 //
 //#define ENABLE_WIFI true
 /////////////////////////////////////////////////////////////////////////////////////
 //
 // DEFINE WiFi Parameters (only in effect if WIFI is on)
 //
 // If DONT_TOUCH_WIFI_CONF is set, all WIFI config will be done with
 // the <+> commands and this sketch will not change anything over
 // AT commands and the other WIFI_* defines below do not have any effect.
 //#define DONT_TOUCH_WIFI_CONF
 //
 // WIFI_SSID is the network name IF you want to use your existing home network.
 // Do NOT change this if you want to use the WiFi in Access Point (AP) mode. 
 //
 // If you do NOT set the WIFI_SSID, the WiFi chip will first try
 // to connect to the previously configured network and if that fails
 // fall back to Access Point mode. The SSID of the AP will be
 // automatically set to DCCEX_*.
 //
 // Your SSID may not conain ``"'' (double quote, ASCII 0x22).
 #define WIFI_SSID "Your network name"
 //
 // WIFI_PASSWORD is the network password for your home network or if
 // you want to change the password from default AP mode password
 // to the AP password you want. 
 // Your password may not conain ``"'' (double quote, ASCII 0x22).
 #define WIFI_PASSWORD "deadcafe"
 //
 // WIFI_HOSTNAME: You probably don't need to change this
 #define WIFI_HOSTNAME "dccex"
 //
 /////////////////////////////////////////////////////////////////////////////////////
 //
 // Wifi connect timeout in milliseconds. Default is 14000 (14 seconds). You only need
 // to set this if you have an extremely slow Wifi router.
 //
 #define WIFI_CONNECT_TIMEOUT 14000
 /////////////////////////////////////////////////////////////////////////////////////
 //
 // ENABLE_ETHERNET: Set to true if you have an Arduino Ethernet card (wired). This
 // is not for Wifi. You will then need the Arduino Ethernet library as well
 //
 //#define ENABLE_ETHERNET true
 /////////////////////////////////////////////////////////////////////////////////////
 //
 // DEFINE STATIC IP ADDRESS *OR* COMMENT OUT TO USE DHCP
 //
 //#define IP_ADDRESS { 192, 168, 1, 31 }
 /////////////////////////////////////////////////////////////////////////////////////
 //
 // DEFINE MAC ADDRESS ARRAY FOR ETHERNET COMMUNICATIONS INTERFACE
 //
 // Uncomment to use with Ethernet Shields
 //
 // Ethernet Shields do not have have a MAC address in hardware. There may be one on 
 // a sticker on the Shield that you should use. Otherwise choose one of the ones below
 // Be certain that no other device on your network has this same MAC address!
 //
 // 52:b8:8a:8e:ce:21
 // e3:e9:73:e1:db:0d
 // 54:2b:13:52:ac:0c
 // NOTE: This is not used with ESP8266 WiFi modules.
 //#define MAC_ADDRESS { 0x52, 0xB8, 0x8A, 0x8E, 0xCE, 0x21 }      // MAC address of your networking card found on the sticker on your card or take one from above
 // 
 // #define MAC_ADDRESS {  0xDE, 0xAD, 0xBE, 0xEF, 0xFE, 0xEF }
 /////////////////////////////////////////////////////////////////////////////////////
 //
 // DEFINE LCD SCREEN USAGE BY THE BASE STATION
 //
 // Note: This feature requires an I2C enabled LCD screen using a Hitachi  HD44780
 //       controller and a PCF8574 based I2C 'backpack',
 //       OR an I2C Oled screen based on SSD1306 (128x64 or 128x32) controller,
 //       OR an I2C Oled screen based on SH1106 (132x64) controller.
 // To enable, uncomment one of the lines below
 // define LCD_DRIVER for I2C LCD address 0x3f,16 cols, 2 rows
 //#define LCD_DRIVER  {SubBus_4,0x27},20,4
 //OR define OLED_DRIVER width,height in pixels (address auto detected) 
 #if defined(ARDUINO_ARCH_STM32) 
 #define OLED_DRIVER 0x3c, 128, 64
 #else
 #define OLED_DRIVER {SubBus_0,0x3c}, 128, 32
 #endif
 #define SCROLLMODE 1
 /////////////////////////////////////////////////////////////////////////////////////
 // DISABLE EEPROM
 //
 // If you do not need the EEPROM at all, you can disable all the code that saves
 // data in the EEPROM. You might want to do that if you are in a Arduino UNO
 // and want to use the EX-RAIL automation. Otherwise you do not have enough RAM
 // to do that. Of course, then none of the EEPROM related commands work.
 //
 #define DISABLE_EEPROM
 /////////////////////////////////////////////////////////////////////////////////////
 //
 // DEFINE TURNOUTS/ACCESSORIES FOLLOW NORM RCN-213
 //
 // According to norm RCN-213 a DCC packet with a 1 is closed/straight
 // and one with a 0 is thrown/diverging.  In DCC++ Classic, and in previous
 // versions of DCC++EX, a turnout throw command was implemented in the packet as 
 // '1' and a close command as '0'. The #define below makes the states
 // match with the norm.  But we don't want to cause havoc on existent layouts,
 // so we define this only for new installations. If you don't want this,
 // don't add it to your config.h.
 //#define DCC_TURNOUTS_RCN_213
 // The following #define likewise inverts the behaviour of the <a> command 
 // for triggering DCC Accessory Decoders, so that <a addr subaddr 0> generates a 
 // DCC packet with D=1 (close turnout) and <a addr subaddr 1> generates D=0 
 // (throw turnout).
 //#define DCC_ACCESSORY_RCN_213
 /////////////////////////////////////////////////////////////////////////////////////
--- a/defines.h
+++ b/defines.h
@ -144,10 +144,9 @@
    #define DISABLE_EEPROM
  #endif
  // STM32 support for native I2C is awaiting development 
-  #ifndef I2C_USE_WIRE
+  // #ifndef I2C_USE_WIRE
-  #define I2C_USE_WIRE
+  // #define I2C_USE_WIRE
-  #endif
+  // #endif
 /* TODO when ready 
 #elif defined(ARDUINO_ARCH_RP2040)
@ -183,6 +182,15 @@
  #define WIFI_ON false
 #endif
 #ifndef WIFI_FORCE_AP
  #define WIFI_FORCE_AP false
 #else
  #if WIFI_FORCE_AP==true || WIFI_FORCE_AP==false
  #else
    #error WIFI_FORCE_AP needs to be true or false
  #endif
 #endif
 #if ENABLE_ETHERNET
  #if defined(HAS_ENOUGH_MEMORY)
    #define ETHERNET_ON true
@ -205,8 +213,21 @@
 //
 #define WIFI_SERIAL_LINK_SPEED 115200
 ////////////////////////////////////////////////////////////////////////////////
 //
 // Define symbol IO_NO_HAL to reduce FLASH footprint when HAL features not required
 // The HAL is disabled by default on Nano and Uno platforms, because of limited flash space.
 // 
 #if defined(ARDUINO_AVR_NANO) || defined(ARDUINO_AVR_UNO)
  #if defined(DISABLE_DIAG) && defined(DISABLE_EEPROM) && defined(DISABLE_PROG)
    #warning you have sacrificed DIAG for HAL
  #else
    #define IO_NO_HAL
  #endif
 #endif
 #if __has_include ( "myAutomation.h")
-  #if defined(HAS_ENOUGH_MEMORY) || defined(DISABLE_EEPROM)
+  #if defined(HAS_ENOUGH_MEMORY) || defined(DISABLE_EEPROM) || defined(DISABLE_PROG)
    #define EXRAIL_ACTIVE
  #else
    #define EXRAIL_WARNING
--- a/install_via_powershell.cmd
+++ b/install_via_powershell.cmd
@ -0,0 +1,13 @@
@ECHO OFF
 FOR /f "tokens=*" %%a IN ('powershell Get-ExecutionPolicy -Scope CurrentUser') DO SET PS_POLICY=%%a
 IF NOT %PS_POLICY=="Bypass" (
  powershell Set-ExecutionPolicy -Scope CurrentUser Bypass
 )
 powershell %~dp0%installer.ps1
 IF NOT %PS_POLICY=="Bypass" (
  powershell Set-ExecutionPolicy -Scope CurrentUser %PS_POLICY%
 )
--- a/installer.ps1
+++ b/installer.ps1
@ -0,0 +1,540 @@
 <#
 # © 2023 Peter Cole
 # 
 # This file is part of EX-CommandStation
 #
 # 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/>.
 #>
 <############################################
 For script errors set ExecutionPolicy:
 Set-ExecutionPolicy -Scope CurrentUser -ExecutionPolicy Bypass
 ############################################>
 <############################################
 Optional command line parameters:
  $buildDirectory - specify an existing directory rather than generating a new unique one
  $configDirectory - specify a directory containing existing files as per $configFiles
 ############################################>
 Param(
  [Parameter()]
  [String]$buildDirectory,
  [Parameter()]
  [String]$configDirectory
 )
 <############################################
 Define global parameters here such as known URLs etc.
 ############################################>
 $installerVersion = "v0.0.8"
 $configFiles = @("config.h", "myAutomation.h", "myHal.cpp", "mySetup.h")
 $wifiBoards = @("arduino:avr:mega", "esp32:esp32:esp32")
 $userDirectory = $env:USERPROFILE + "\"
 $gitHubAPITags = "https://api.github.com/repos/DCC-EX/CommandStation-EX/git/refs/tags"
 $gitHubURLPrefix = "https://github.com/DCC-EX/CommandStation-EX/archive/"
 if ((Get-WmiObject win32_operatingsystem | Select-Object osarchitecture).osarchitecture -eq "64-bit") {
  $arduinoCLIURL = "https://downloads.arduino.cc/arduino-cli/arduino-cli_latest_Windows_64bit.zip"
  $arduinoCLIZip = $userDirectory + "Downloads\" + "arduino-cli_latest_Windows_64bit.zip"
 } else {
  $arduinoCLIURL = "https://downloads.arduino.cc/arduino-cli/arduino-cli_latest_Windows_32bit.zip"
  $arduinoCLIZip = $userDirectory + "Downloads\" + "arduino-cli_latest_Windows_32bit.zip"
 }
 $arduinoCLIDirectory = $userDirectory + "arduino-cli"
 $arduinoCLI = $arduinoCLIDirectory + "\arduino-cli.exe"
 <############################################
 List of supported devices with FQBN in case clones used that aren't detected
 ############################################>
 $supportedDevices = @(
  @{
    name = "Arduino Mega or Mega 2560"
    fqbn = "arduino:avr:mega"
  },
  @{
    name = "Arduino Nano"
    fqbn = "arduino:avr:nano"
  },
  @{
    name = "Arduino Uno"
    fqbn = "arduino:avr:uno"
  },
  @{
    name = "ESP32 Dev Module"
    fqbn = "esp32:esp32:esp32"
  }
 )
 <############################################
 List of supported displays
 ############################################>
 $displayList = @(
  @{
    option = "LCD 16 columns x 2 rows"
    configLine = "#define LCD_DRIVER  0x27,16,2"
  },
  @{
    option = "LCD 16 columns x 4 rows"
    configLine = "#define LCD_DRIVER  0x27,16,4"
  },
  @{
    option = "OLED 128 x 32"
    configLine = "#define OLED_DRIVER 128,32"
  },
  @{
    option = "OLED 128 x 64"
    configLine = "#define OLED_DRIVER 128,64"
  }
 )
 <############################################
 Basics of config.h
 ############################################>
 $configLines = @(
  "/*",
  "This config.h file was generated by the DCC-EX PowerShell installer $installerVersion",
  "*/",
  "",
  "// Define standard motor shield",
  "#define MOTOR_SHIELD_TYPE STANDARD_MOTOR_SHIELD",
  ""
 )
 <############################################
 Set default action for progress indicators, warnings, and errors
 ############################################>
 $global:ProgressPreference = "SilentlyContinue"
 $global:WarningPreference = "SilentlyContinue"
 $global:ErrorActionPreference = "SilentlyContinue"
 <############################################
 If $buildDirectory not provided, generate a new time/date stamp based directory to use
 ############################################>
 if (!$PSBoundParameters.ContainsKey('buildDirectory')) {
  $buildDate = Get-Date -Format 'yyyyMMdd-HHmmss'
  $buildDirectory = $userDirectory + "EX-CommandStation-Installer\" + $buildDate
 }
 $commandStationDirectory = $buildDirectory + "\CommandStation-EX"
 <############################################
 Write out intro message and prompt to continue
 ############################################>
@"
 Welcome to the DCC-EX PowerShell installer for EX-CommandStation ($installerVersion)
 Current installer options:
 - EX-CommandStation will be built in $commandStationDirectory
 - Arduino CLI will downloaded and extracted to $arduinoCLIDirectory
 Before continuing, please ensure:
 - Your computer is connected to the internet
 - The device you wish to install EX-CommandStation on is connected to a USB port
 This installer will obtain the Arduino CLI (if not already present), and then download and install your chosen version of EX-CommandStation
 "@
 <############################################
 Prompt user to confirm all is ready to proceed
 ############################################>
 $confirmation = Read-Host "Enter 'Y' or 'y' then press <Enter> to confirm you are ready to proceed, any other key to exit"
 if ($confirmation -ne "Y" -and $confirmation -ne "y") {
  Exit
 }
 <############################################
 See if we have the Arduino CLI already, otherwise download and extract it
 ############################################>
 if (!(Test-Path -PathType Leaf -Path $arduinoCLI)) {
  if (!(Test-Path -PathType Container -Path $arduinoCLIDirectory)) {
    try {
      New-Item -ItemType Directory -Path $arduinoCLIDirectory | Out-Null
    }
    catch {
      Write-Output "Arduino CLI does not exist and cannot create directory $arduinoCLIDirectory"
      Exit
    }
  }
  Write-Output "`r`nDownloading and extracting Arduino CLI"
  try {
    Invoke-WebRequest -Uri $arduinoCLIURL -OutFile $arduinoCLIZip
  }
  catch {
    Write-Output "Failed to download Arduino CLI"
    Exit
  }
  try {
    Expand-Archive -Path $arduinoCLIZip -DestinationPath $arduinoCLIDirectory -Force
  }
  catch {
    Write-Output "Failed to extract Arduino CLI"
  }
 } else {
  Write-Output "`r`nArduino CLI already downloaded, ensuring it is up to date and you have a board connected"
 }
 <############################################
 Make sure Arduino CLI core index updated and list of boards populated
 ############################################>
 # Need to do an initial board list to download everything first
 try {
  & $arduinoCLI core update-index | Out-Null
 }
 catch {
  Write-Output "Failed to update Arduino CLI core index"
  Exit
 }
 # Need to do an initial board list to download everything first
 try {
  & $arduinoCLI board list | Out-Null
 }
 catch {
  Write-Output "Failed to update Arduino CLI board list"
  Exit
 }
 <############################################
 Identify available board(s)
 ############################################>
 try {
  $boardList = & $arduinoCLI board list --format jsonmini | ConvertFrom-Json
 }
 catch {
  Write-Output "Failed to obtain list of boards"
  Exit
 }
 <############################################
 Get user to select board
 ############################################>
 if ($boardList.count -eq 0) {
  Write-Output "Could not find any attached devices, please ensure your device is plugged in to a USB port and Windows recognises it"
  Exit
 } else {
@"
 Devices attached to COM ports:
 ------------------------------
 "@
  $boardSelect = 1
  foreach ($board in $boardList) {
    if ($board.matching_boards.name) {
      $boardName = $board.matching_boards.name
    } else {
      $boardName = "Unknown device"
    }
    $port = $board.port.address
    Write-Output "$boardSelect - $boardName on port $port"
    $boardSelect++
  }
  Write-Output "$boardSelect - Exit"
  $userSelection = 0
  do {
    [int]$userSelection = Read-Host "`r`nSelect the device to use from the list above"
  } until (
    (($userSelection -ge 1) -and ($userSelection -le ($boardList.count + 1)))
  )
  if ($userSelection -eq ($boardList.count + 1)) {
    Write-Output "Exiting installer"
    Exit
  } else {
    $selectedBoard = $userSelection - 1
  }
 }
 <############################################
 If the board is unknown, need to choose which one
 ############################################>
 if ($null -eq $boardList[$selectedBoard].matching_boards.name) {
  Write-Output "The device selected is unknown, these boards are supported:`r`n"
  $deviceSelect = 1
  foreach ($device in $supportedDevices) {
    Write-Output "$deviceSelect - $($supportedDevices[$deviceSelect - 1].name)"
    $deviceSelect++
  }
  Write-Output "$deviceSelect - Exit"
  $userSelection = 0
  do {
    [int]$userSelection = Read-Host "Select the board type from the list above"
  } until (
    (($userSelection -ge 1) -and ($userSelection -le ($supportedDevices.count + 1)))
  )
  if ($userSelection -eq ($supportedDevices.count + 1)) {
    Write-Output "Exiting installer"
    Exit
  } else {
    $deviceName = $supportedDevices[$userSelection - 1].name
    $deviceFQBN = $supportedDevices[$userSelection - 1].fqbn
    $devicePort = $boardList[$selectedBoard].port.address
  }
 } else {
  $deviceName = $boardList[$selectedBoard].matching_boards.name
  $deviceFQBN = $boardList[$selectedBoard].matching_boards.fqbn
  $devicePort = $boardList[$selectedBoard].port.address
 }
 <############################################
 Get the list of tags
 ############################################>
 try {
  $gitHubTags = Invoke-RestMethod -Uri $gitHubAPITags
 }
 catch {
  Write-Output "Failed to obtain list of available EX-CommandStation versions"
  Exit
 }
 <############################################
 Get our GitHub tag list in a hash so we can sort by version numbers and extract just the ones we want
 ############################################>
 $versionMatch = ".*?v(\d+)\.(\d+).(\d+)-(.*)"
 $tagList = @{}
 foreach ($tag in $gitHubTags) {
  $tagHash = @{}
  $tagHash["Ref"] = $tag.ref
  $version = $tag.ref.split("/")[2]
  $null = $version -match $versionMatch
  $tagHash["Major"] = [int]$Matches[1]
  $tagHash["Minor"] = [int]$Matches[2]
  $tagHash["Patch"] = [int]$Matches[3]
  $tagHash["Type"] = $Matches[4]
  $tagList.Add($version, $tagHash)
 }
 <############################################
 Get latest two Prod and Devel for user to select
 ############################################>
 $userList = @{}
 $prodCount = 1
 $devCount = 1
 $select = 1
 foreach ($tag in $tagList.Keys | Sort-Object {$tagList[$_]["Major"]},{$tagList[$_]["Minor"]},{$tagList[$_]["Patch"]} -Descending) {
  if (($tagList[$tag]["Type"] -eq "Prod") -and $prodCount -le 2) {
    $userList[$select] = $tag
    $select++
    $prodCount++
  } elseif (($tagList[$tag]["Type"] -eq "Devel") -and $devCount -le 2) {
    $userList[$select] = $tag
    $select++
    $devCount++
  }
 }
 <############################################
 Display options for user to select and get the selection
 ############################################>
@"
 Available EX-CommandStation versions:
 -------------------------------------
 "@
 foreach ($selection in $userList.Keys | Sort-Object $selection) {
  Write-Output "$selection - $($userList[$selection])"
 }
 Write-Output "5 - Exit"
 $userSelection = 0
 do {
  [int]$userSelection = Read-Host "`r`nSelect the version to install from the list above (1 - 5)"
 } until (
  (($userSelection -ge 1) -and ($userSelection -le 5))
 )
 if ($userSelection -eq 5) {
  Write-Output "Exiting installer"
  Exit
 } else {
  $downloadURL = $gitHubURLPrefix + $tagList[$userList[$userSelection]]["Ref"] + ".zip"
 }
 <############################################
 Create build directory if it doesn't exist, or fail
 ############################################>
 if (!(Test-Path -PathType Container -Path $buildDirectory)) {
  try {
    New-Item -ItemType Directory -Path $buildDirectory | Out-Null
  }
  catch {
    Write-Output "Could not create build directory $buildDirectory"
    Exit
  }
 }
 <############################################
 Download the chosen version to the build directory
 ############################################>
 $downladFile = $buildDirectory + "\CommandStation-EX.zip"
 Write-Output "Downloading and extracting $($userList[$userSelection])"
 try {
  Invoke-WebRequest -Uri $downloadURL -OutFile $downladFile
 }
 catch {
  Write-Output "Error downloading EX-CommandStation zip file"
  Exit
 }
 <############################################
 If folder exists, bail out and tell user
 ############################################>
 if (Test-Path -PathType Container -Path "$buildDirectory\CommandStation-EX") {
  Write-Output "EX-CommandStation directory already exists, please ensure you have copied any user files then delete manually: $buildDirectory\CommandStation-EX"
  Exit
 }
 <############################################
 Extract and rename to CommandStation-EX to allow building
 ############################################>
 try {
  Expand-Archive -Path $downladFile -DestinationPath $buildDirectory -Force
 }
 catch {
  Write-Output "Failed to extract EX-CommandStation zip file"
  Exit
 }
 $folderName = $buildDirectory + "\CommandStation-EX-" + ($userList[$userSelection] -replace "^v", "")
 try {
  Rename-Item -Path $folderName -NewName $commandStationDirectory
 }
 catch {
  Write-Output "Could not rename folder"
  Exit
 }
 <############################################
 If config directory provided, copy files here
 ############################################>
 if ($PSBoundParameters.ContainsKey('configDirectory')) {
  if (Test-Path -PathType Container -Path $configDirectory) {
    foreach ($file in $configFiles) {
      if (Test-Path -PathType Leaf -Path "$configDirectory\$file") {
        Copy-Item -Path "$configDirectory\$file" -Destination "$commandStationDirectory\$file"
      }
    }
  } else {
    Write-Output "User provided configuration directory $configDirectory does not exist, skipping"
  }
 } else {
 <############################################
 If no config directory provided, prompt for display option
 ############################################>
  Write-Output "`r`nIf you have an LCD or OLED display connected, you can configure it here`r`n"
  Write-Output "1 - I have no display, skip this step"
  $displaySelect = 2
  foreach ($display in $displayList) {
    Write-Output "$displaySelect - $($displayList[$displaySelect - 2].option)"
    $displaySelect++
  }
  Write-Output "$($displayList.Count + 2) - Exit"
  do {
    [int]$displayChoice = Read-Host "`r`nSelect a display option"
  } until (
    ($displayChoice -ge 1 -and $displayChoice -le ($displayList.Count + 2))
  )
  if ($displayChoice -eq ($displayList.Count + 2)) {
    Exit
  } elseif ($displayChoice -ge 2) {
    $configLines+= "// Display configuration"
    $configLines+= "$($displayList[$displayChoice - 2].configLine)"
    $configLines+= "#define SCROLLMODE 1 // Alternate between pages"
  }
 <############################################
 If device supports WiFi, prompt to configure
 ############################################>
  if ($wifiBoards.Contains($deviceFQBN)) {
    Write-Output "`r`nYour chosen board supports WiFi`r`n"
    Write-Output "1 - I don't want WiFi, skip this step
 2 - Configure my device as an access point I will connect to directly
 3 - Configure my device to connect to my home WiFi network
 4 - Exit"
    do {
      [int]$wifiChoice = Read-Host "`r`nSelect a WiFi option"
    } until (
      ($wifiChoice -ge 1 -and $wifiChoice -le 4)
    )
    if ($wifiChoice -eq 4) {
      Exit
    } elseif ($wifiChoice -ne 1) {
      $configLines+= ""
      $configLines+= "// WiFi configuration"
      $configLines+= "#define ENABLE_WIFI true"
      $configLines+= "#define IP_PORT 2560"
      $configLines+= "#define WIFI_HOSTNAME ""dccex"""
      $configLines+= "#define WIFI_CHANNEL 1"
      if ($wifiChoice -eq 2) {
        $configLines+= "#define WIFI_SSID ""Your network name"""
        $configLines+= "#define WIFI_PASSWORD ""Your network passwd"""
      }
      if ($wifiChoice -eq 3) {
        $wifiSSID = Read-Host "Please enter the SSID of your home network here"
        $wifiPassword = Read-Host "Please enter your home network WiFi password here"
        $configLines+= "#define WIFI_SSID ""$($wifiSSID)"""
        $configLines+= "#define WIFI_PASSWORD ""$($wifiPassword)"""
      }
    }
  }
 <############################################
 Write out config.h to a file here only if config directory not provided
 ############################################>
  $configH = $commandStationDirectory + "\config.h"
  try {
    $configLines | Out-File -FilePath $configH -Encoding ascii
  }
  catch {
    Write-Output "Error writing config file to $configH"
    Exit
  }
 }
 <############################################
 Install core libraries for the platform
 ############################################>
 $platformArray = $deviceFQBN.split(":")
 $platform = $platformArray[0] + ":" + $platformArray[1]
 try {
  & $arduinoCLI core install $platform
 }
 catch {
  Write-Output "Error install core libraries"
  Exit
 }
 <############################################
 Upload the sketch to the selected board
 ############################################>
 #$arduinoCLI upload -b fqbn -p port $commandStationDirectory
 Write-Output "Compiling and uploading to $deviceName on $devicePort"
 try {
  $output = & $arduinoCLI compile -b $deviceFQBN -u -t -p $devicePort $commandStationDirectory --format jsonmini | ConvertFrom-Json
 }
 catch {
  Write-Output "Failed to compile"
  Exit
 }
 if ($output.success -eq "True") {
  Write-Output "`r`nCongratulations! DCC-EX EX-CommandStation $($userList[$userSelection]) has been installed on your $deviceName`r`n"
 } else {
  Write-Output "`r`nThere was an error installing $($userList[$userSelection]) on your $($deviceName), please take note of the errors provided:`r`n"
  if ($null -ne $output.compiler_err) {
    Write-Output "Compiler error: $($output.compiler_err)`r`n"
  }
  if ($null -ne $output.builder_result) {
    Write-Output "Builder result: $($output.builder_result)`r`n"
  }
 }
 Write-Output "`r`nPress any key to exit the installer"
 [void][System.Console]::ReadKey($true)
--- a/installer.sh
+++ b/installer.sh
@ -1,7 +1,7 @@
 #!/bin/bash
 #
-# © 2022 Harald Barth
+# © 2022,2023 Harald Barth
 # 
 # This file is part of CommandStation-EX
 #
@ -29,14 +29,33 @@ ACLI="./bin/arduino-cli"
 function need () {
    type -p $1 > /dev/null && return
    dpkg -l $1 2>&1 | egrep ^ii >/dev/null && return
    sudo apt-get install $1
    type -p $1 > /dev/null && return
    echo "Could not install $1, abort"
    exit 255
 }
 need git
 if cat /etc/issue | egrep '^Raspbian' 2>&1 >/dev/null ; then
    # we are on a raspi where we do not support graphical
    unset DISPLAY
 fi
 if [ x$DISPLAY != x ] ; then
    # we have DISPLAY, do the graphic thing
    need python3-tk
    need python3.8-venv
    mkdir -p ~/ex-installer/venv
    python3 -m venv ~/ex-installer/venv
    cd ~/ex-installer/venv || exit 255
    source ./bin/activate
    git clone https://github.com/DCC-EX/EX-Installer
    cd EX-Installer || exit 255
    pip3 install -r requirements.txt
    exec python3 -m ex_installer
 fi
 if test -d `basename "$DCCEXGITURL"` ; then
    : assume we are almost there
    cd `basename "$DCCEXGITURL"` || exit 255
@ -69,10 +88,10 @@ else
    # need to do this config better
    cp -p config.example.h config.h
 fi
 need curl
 if test -x "$ACLI" ; then
    : all well
 else
    need curl
    curl "$ACLIINSTALL" > acliinstall.sh
    chmod +x acliinstall.sh
    ./acliinstall.sh
--- a/myHal.cpp_example.txt
+++ b/myHal.cpp_example.txt
@ -24,6 +24,7 @@
 //#include "IO_TouchKeypad.h  // Touch keypad with 16 keys
 //#include "IO_EXTurntable.h"   // Turntable-EX turntable controller
 //#include "IO_EXFastClock.h"  // FastClock driver
 //#include "IO_PCA9555.h"     // 16-bit I/O expander (NXP & Texas Instruments).
 //==========================================================================
 // The function halSetup() is invoked from CS if it exists within the build.
@ -51,7 +52,7 @@ void halSetup() {
  // Create a 20x4 LCD display device as display number 2 
  // (line 0 is written by EX-RAIL 'SCREEN(2, 0, "text")').
-  // HALDisplay<LiquidCrystal>(2, 0x27, 20, 4);
+  // HALDisplay<LiquidCrystal>::create(2, 0x27, 20, 4);
  //=======================================================================
--- a/platformio.ini
+++ b/platformio.ini
@ -20,18 +20,17 @@ default_envs =
 	ESP32
 	Nucleo-F411RE
 	Nucleo-F446RE
-	Teensy3.2
+	Teensy3_2
-	Teensy3.5
+	Teensy3_5
-	Teensy3.6
+	Teensy3_6
-	Teensy4.0
+	Teensy4_0
-	Teensy4.1
+	Teensy4_1
 src_dir = .
 include_dir = .
 [env]
 build_flags = -Wall -Wextra
-monitor_filters = time
+; monitor_filters = time
 ; lib_deps = adafruit/Adafruit ST7735 and ST7789 Library @ ^1.10.0
 [env:samd21-dev-usb]
 platform = atmelsam
@ -53,14 +52,14 @@ monitor_speed = 115200
 monitor_echo = yes
 build_flags = -std=c++17
-[env:Arduino M0]
+[env:Arduino-M0]
 platform = atmelsam
 board = mzeroUSB
 framework = arduino
 lib_deps = ${env.lib_deps}
 monitor_speed = 115200
 monitor_echo = yes
-build_flags = -std=c++17 ; -DI2C_USE_WIRE  -DDIAG_LOOPTIMES -DDIAG_IO
+build_flags = -std=c++17
 [env:mega2560-debug]
 platform = atmelavr
@ -72,7 +71,7 @@ lib_deps =
 	SPI
 monitor_speed = 115200
 monitor_echo = yes
-build_flags =  -DDIAG_IO=2 -DDIAG_LOOPTIMES
+build_flags = -DDIAG_IO=2 -DDIAG_LOOPTIMES
 [env:mega2560-no-HAL]
 platform = atmelavr
@ -108,7 +107,7 @@ lib_deps =
 	SPI
 monitor_speed = 115200
 monitor_echo = yes
-build_flags =     ; -DDIAG_LOOPTIMES
+build_flags = 
 [env:mega328]
 platform = atmelavr
@ -173,6 +172,8 @@ board = esp32dev
 framework = arduino
 lib_deps = ${env.lib_deps}
 build_flags = -std=c++17
 monitor_speed = 115200
 monitor_echo = yes
 [env:Nucleo-F411RE]
 platform = ststm32
@ -188,11 +189,76 @@ platform = ststm32
 board = nucleo_f446re
 framework = arduino
 lib_deps = ${env.lib_deps}
-build_flags = -std=c++17  -Os -g2 -Wunused-variable -DDIAG_LOOPTIMES ; -DDIAG_IO 
+build_flags = -std=c++17  -Os -g2 -Wunused-variable
 monitor_speed = 115200
 monitor_echo = yes
-[env:Teensy3.2]
+; Experimental - no reason this should not work, but not
 ; tested as yet
 ;
 [env:Nucleo-F401RE]
 platform = ststm32
 board = nucleo_f401re
 framework = arduino
 lib_deps = ${env.lib_deps}
 build_flags = -std=c++17  -Os -g2 -Wunused-variable
 monitor_speed = 115200
 monitor_echo = yes
 ; Commented out by default as the F13ZH has variant files
 ; but NOT the nucleo_f413zh.json file which needs to be
 ; installed before you can let PlatformIO see this
 ;
 ; [env:Nucleo-F413ZH]
 ; platform = ststm32
 ; board = nucleo_f413zh
 ; framework = arduino
 ; lib_deps = ${env.lib_deps}
 ; build_flags = -std=c++17  -Os -g2 -Wunused-variable
 ; monitor_speed = 115200
 ; monitor_echo = yes
 ; Commented out by default as the F446ZE needs variant files
 ; installed before you can let PlatformIO see this
 ;
 ; [env:Nucleo-F446ZE]
 ; platform = ststm32
 ; board = nucleo_f446ze
 ; framework = arduino
 ; lib_deps = ${env.lib_deps}
 ; build_flags = -std=c++17  -Os -g2 -Wunused-variable
 ; monitor_speed = 115200
 ; monitor_echo = yes
 ; Commented out by default as the F412ZG needs variant files
 ; installed before you can let PlatformIO see this
 ;
 ; [env:Nucleo-F412ZG]
 ; platform = ststm32
 ; board = blah_f412zg
 ; framework = arduino
 ; lib_deps = ${env.lib_deps}
 ; build_flags = -std=c++17 -Os -g2 -Wunused-variable
 ; monitor_speed = 115200
 ; monitor_echo = yes
 ; upload_protocol = stlink
 ; Experimental - Ethernet work still in progress
 ;
 ; [env:Nucleo-F429ZI]
 ; platform = ststm32
 ; board = nucleo_f429zi
 ; framework = arduino
 ; lib_deps = ${env.lib_deps}
 ; 			arduino-libraries/Ethernet @ ^2.0.1
 ; 			stm32duino/STM32Ethernet @ ^1.3.0
 ; 			stm32duino/STM32duino LwIP @ ^2.1.2
 ; build_flags = -std=c++17 -Os -g2 -Wunused-variable
 ; monitor_speed = 115200
 ; monitor_echo = yes
 ; upload_protocol = stlink
 [env:Teensy3_2]
 platform = teensy
 board = teensy31
 framework = arduino
@ -200,7 +266,7 @@ build_flags = -std=c++17  -Os -g2
 lib_deps = ${env.lib_deps}
 lib_ignore = NativeEthernet
-[env:Teensy3.5]
+[env:Teensy3_5]
 platform = teensy
 board = teensy35
 framework = arduino
@ -208,7 +274,7 @@ build_flags = -std=c++17  -Os -g2
 lib_deps = ${env.lib_deps}
 lib_ignore = NativeEthernet
-[env:Teensy3.6]
+[env:Teensy3_6]
 platform = teensy
 board = teensy36
 framework = arduino
@ -216,7 +282,7 @@ build_flags = -std=c++17  -Os -g2
 lib_deps = ${env.lib_deps}
 lib_ignore = NativeEthernet
-[env:Teensy4.0]
+[env:Teensy4_0]
 platform = teensy
 board = teensy40
 framework = arduino
@ -224,11 +290,10 @@ build_flags = -std=c++17  -Os -g2
 lib_deps = ${env.lib_deps}
 lib_ignore = NativeEthernet
-[env:Teensy4.1]
+[env:Teensy4_1]
 platform = teensy
 board = teensy41
 framework = arduino
 build_flags = -std=c++17  -Os -g2
 lib_deps = ${env.lib_deps}
 lib_ignore =
--- a/version.h
+++ b/version.h
@ -3,8 +3,76 @@
 #include "StringFormatter.h"
-
+#define VERSION "5.1.16"
-#define VERSION "4.2.41"
+// 5.1.16 - Remove I2C address from EXTT_TURNTABLE macro to work with MUX, requires separate HAL macro to create
 // 5.1.15 - LCC/Adapter support and Exrail feature-compile-out.
 // 5.1.14 - Fixed IFTTPOSITION
 // 5.1.13 - Changed turntable broadcast from i to I due to server string conflict
 // 5.1.12 - Added Power commands <0 A> & <1 A> etc. and update to <=>
 //          Added EXRAIL SET_POWER(track, ON/OFF)
 //          Fixed a problem whereby <1 MAIN> also powered on PROG track
 //          Added functions to TrackManager.cpp to allow UserAddin code for power display on OLED/LCD
 //          Added - returnMode(byte t), returnDCAddr(byte t) & getModeName(byte Mode)
 // 5.1.11 - STM32F4xx revised I2C clock setup, no correctly sets clock and has fully variable frequency selection
 // 5.1.10 - STM32F4xx DCCEXanalogWrite to handle PWM generation for TrackManager DC/DCX
 //        - STM32F4xx DCC 58uS timer now using non-PWM output timers where possible
 //        - ESP32 brakeCanPWM check now detects UNUSED_PIN
 //        - ARM architecture brakeCanPWM now uses digitalPinHasPWM()
 //        - STM32F4xx shadowpin extensions to handle pins on ports D, E and F
 // 5.1.9  - Fixed IO_PCA9555'h to work with PCA9548 mux, tested OK
 // 5.1.8  - STM32Fxx ADCee extension to support ADCs #2 and #3
 // 5.1.7  - Fix turntable broadcasts for non-movement activities and <JP> result
 // 5.1.6  - STM32F4xx native I2C driver added
 // 5.1.5  - Added turntable object and EXRAIL commands
 //        - <I ...>, <JO ...>, <JP ...> - turntable commands
 //        - DCC_TURNTABLE, EXTT_TURNTABLE, IFTTPOSITION, ONROTATE, ROTATE, ROTATE_DCC, TT_ADDPOSITION, WAITFORTT EXRAIL
 // 5.1.4  - Added ONOVERLOAD & AFTEROVERLOAD to EXRAIL
 // 5.1.3  - Make parser more fool proof
 // 5.1.2  - Bugfix: ESP32 30ms off time
 // 5.1.1  - Check bad AT firmware version
 //        - Update IO_PCA9555.h reflecting IO_MCP23017.h changes to support PCA9548 mux
 // 5.0.1  - Bugfix: execute 30ms off time before rejoin
 // 5.0.0  - Make 4.2.69 the 5.0.0 release
 // 4.2.69 - Bugfix: Make <!> work in DC mode
 // 4.2.68 - Rename track mode OFF to NONE
 // 4.2.67 - AVR: Pin specific timer register seting
 //        - Protect Uno user from choosing DC(X)
 //        - More Nucleo variant defines
 //        - GPIO PCA9555 / TCA9555 support
 // 4.2.66 - Throttle inrush current by applying PWM to brake pin when
 //          fault pin goes active
 // 4.2.65 - new config WIFI_FORCE_AP option
 // 4.2.63 - completely new overcurrent detection
 //        - ESP32 protect from race in RMT code
 // 4.2.62 - Update IO_RotaryEncoder.h to ignore sending current position
 //        - Update IO_EXTurntable.h to remove forced I2C clock speed
 //        - Show device offline if EX-Turntable not connected
 // 4.2.61 - MAX_CURRENT restriction (caps motor shield value)
 // 4.2.60 - Add mDNS capability to ESP32 for autodiscovery
 // 4.2.59 - Fix: AP SSID was DCC_ instead of DCCEX_
 // 4.2.58 - Start motordriver as soon as possible but without waveform
 // 4.2.57 - New overload handling (faster and handles commonFaultPin again)
 //        - Optimize analog read STM32
 // 4.2.56 - Update IO_RotaryEncoder.h:
 //        - Improved I2C communication, non-blocking reads
 //        - Enable sending positions to the encoder from EXRAIL via SERVO()
 // 4.2.55 - Optimize analog read for AVR
 // 4.2.54 - EX8874 shield in config.example.h
 //        - Fix: Better warnings for pin number errors
 //        - Fix: Default roster list possible in Withrottle and <jR>
 //        - Fix: Pin handling supports pins up to 254
 // 4.2.53 - Fix: Fault pin handling made more straight forward
 // 4.2.52 - Experimental support for sabertooth motor controller on ESP32
 // 4.2.51 - Add DISABLE_PROG to disable programming to save RAM/Flash
 // 4.2.50 - Fixes: estop all, turnout eeprom, cab ID check
 // 4.2.49 - Exrail SPEED take notice of external direction change 
 // 4.2.48 - BROADCAST/WITHROTTLE Exrail macros 
 // 4.2.47 - Correct response to <JA 0>
 // 4.2.46 - Support boards with inverted fault pin
 // 4.2.45 - Add ONCLOCKMINS to FastClock to allow hourly repeat events
 // 4.2.44 - Add PowerShell installer EX-CommandStation-installer.exe
 // 4.2.43 - Fix STM32 set right port mode bits for analog
 // 4.2.42 - Added EXRAIL TURNOUTL Macro definition
 // 4.2.41 - Move HAl startup to ASAP in setup()
 //        - Fix DNOU8 output pin setup to all LOW  
 // 4.2.40 - Automatically detect conflicting default I2C devices and disable
@ -72,6 +140,10 @@
 // 4.2.11 Exrail IFLOCO feature added
 // 4.2.10 SIGNAL/SIGNALH bug fix as they were inverted
 //        IO_EXIOExpander.h input speed optimisation
 //        ONCLOCK and ONCLOCKTIME command added to EXRAIL for EX-FastCLock
 //        <JC> Serial command added for EX-FastClock
 //        <jC> Broadcast added for EX-FastClock
 //        IO_EXFastClock.h added for I2C FastClock connection
 // 4.2.9 duinoNodes support
 // 4.2.8 HIGHMEM (EXRAIL support beyond 64kb)
 //       Withrottle connect/disconnect improvements
`@ -1 +1 @@`
	`#define GITHUB_SHA "devel-202303252126Z"`	`#define GITHUB_SHA "devel-202309241855Z"`