/* * © 2020, Chris Harlow. All rights reserved. * * This file is part of Asbelos DCC 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 . */ /* * Truncated JMRI WiThrottle server implementation for DCC-EX command station * Credit is due to Valerie Valley RR https://sites.google.com/site/valerievalleyrr/ * for showing how it could be done, but this code is very different to the original * implemenatatin as it is designed to run on the Arduino and not the ESP and is * also calling directly into the DCCEX Api rather than simulating JMRI text commands. * Refer JMRI WiFi Throttle Communications Protocol https://www.jmri.org/help/en/package/jmri/jmrit/withrottle/Protocol.shtml * * * PROTOTYPE NOTES: * There will be one WiThrottle instance created for each WiThrottle client detected by the WifiInterface. * Some shortcuts have been taken and there are some things that are yet to be included: * e.g. Full response to adding a loco. * What to do about unknown turnouts. * Broadcasting to other WiThrottles when things change. * - Bear in mind that changes may have taken place due to * other WiThrottles, OR JMRI commands received OR TPL automation. * - I suggest that at the end of parse(), then anything that has changed and is of interest could * be notified then. (e.g loco speeds, directions or functions, turnout states. * * WiThrottle.h sets the max locos per client at 10, this is ok to increase but requires just an extra 3 bytes per loco per client. */ #include #include "WiThrottle.h" #include "DCC.h" #include "DCCWaveform.h" #include "StringFormatter.h" #include "Turnouts.h" #include "DIAG.h" #define LOOPLOCOS(THROTTLECHAR, CAB) for (int loco=0;loconextThrottle) if (wt->clientid==wifiClient) return wt; return new WiThrottle( wifiClient); } // One instance of WiTHrottle per connected client, so we know what the locos are WiThrottle::WiThrottle( int wificlientid) { DIAG(F("\nCreating new WiThrottle for client %d\n"),wificlientid); nextThrottle=firstThrottle; firstThrottle= this; clientid=wificlientid; heartBeatEnable=false; // until client turns it on firstCall=true; for (int loco=0;loconextThrottle; return; } for (WiThrottle* wt=firstThrottle; wt!=NULL ; wt=wt->nextThrottle) { if (wt->nextThrottle==this) { wt->nextThrottle=this->nextThrottle; return; } } } void WiThrottle::parse(Print & stream, byte * cmdx) { // we have to take a copy of the cmd buffer as the reply will get built into the cmdx byte local[50]; for (byte i=0;inextTurnout){ StringFormatter::send(stream,F("]\\[LT%d}|{%d}|{%d"), tt->data.id, tt->data.id, (bool)(tt->data.tStatus & STATUS_ACTIVE)); } StringFormatter::send(stream,F("\n*10\n")); } while (cmd[0]) { switch (cmd[0]) { case '*': // heartbeat control if (cmd[1]=='+') heartBeatEnable=true; else if (cmd[1]=='-') heartBeatEnable=false; break; case 'P': if (cmd[1]=='P' && cmd[2]=='A' ) { //PPA power mode DCCWaveform::mainTrack.setPowerMode(cmd[3]=='1'?POWERMODE::ON:POWERMODE::OFF); StringFormatter::send(stream, F("PPA%c\n"),cmd[3]); } else if (cmd[1]=='T' && cmd[2]=='A') { // PTA accessory toggle // TODO... if we are given an address that is not a known Turnout... // should we create one or just send the DCC message. Turnout::activate(getInt(cmd+4),cmd[3]=='T'); } break; case 'N': // Heartbeat (2) StringFormatter::send(stream, F("*10\n")); // 10 second timeout break; case 'M': // multithrottle multithrottle(stream, cmd); break; case 'H': // hardware introduction.... break; case 'Q': // DIAG(F("\nWiThrottle Quit")); delete this; break; } // skip over cmd until 0 or past \r or \n while(*cmd !='\0' && *cmd != '\r' && *cmd !='\n') cmd++; if (*cmd!='\0') cmd++; // skip \r or \n } } int WiThrottle::getInt(byte * cmd) { int i=0; while (cmd[0]>='0' && cmd[0]<='9') { i=i*10 + (cmd[0]-'0'); cmd++; } return i; } int WiThrottle::getLocoId(byte * cmd) { if (cmd[0]=='*') return -1; // match all locos if (cmd[0]!='L' && cmd[0]!='S') return 0; // should not match any locos return getInt(cmd+1); } void WiThrottle::multithrottle(Print & stream, byte * cmd){ char throttleChar=cmd[1]; int locoid=getLocoId(cmd+3); // -1 for * byte * aval=cmd; while(*aval !=';' && *aval !='\0') aval++; if (*aval) aval+=2; // skip ;> DIAG(F("\nMultithrottle aval=%c cab=%d"), aval[0],locoid); switch(cmd[2]) { case '+': // add loco for (int loco=0;loco\n"), throttleChar, cmd[3] ,locoid); // TODO... get known Fn states from DCC (need memoryStream improvements to handle data length) // for(fKey=0; fKey<29; fKey++)StringFormatter::send(stream,F("M%cA%c<;>F0&s\n"),throttleChar,cmd[3],fkey); StringFormatter::send(stream, F("M%c+%c%d<;>V0\n"), throttleChar, cmd[3], locoid); StringFormatter::send(stream, F("M%c+%c%d<;>R1\n"), throttleChar, cmd[3], locoid); StringFormatter::send(stream, F("M%c+%c%d<;>s1\n"), throttleChar, cmd[3], locoid); break; } } break; case '-': // remove loco LOOPLOCOS(throttleChar, locoid) { myLocos[loco].throttle='\0'; DCC::setThrottle(myLocos[loco].cab,0,0); StringFormatter::send(stream, F("M%c-<;>\n"), throttleChar); } break; case 'A': locoAction(stream,aval, throttleChar, locoid); } } void WiThrottle::locoAction(Print & stream, byte* aval, char throttleChar, int cab){ // Note cab=-1 for all cabs in the consist called throttleChar. DIAG(F("\nLoco Action aval=%c%c throttleChar=%c, cab=%d"), aval[0],aval[1],throttleChar, cab); switch (aval[0]) { case 'V': // Vspeed { byte locospeed=getInt(aval+1); LOOPLOCOS(throttleChar, cab) { DCC::setThrottle(myLocos[loco].cab,locospeed, DCC::getThrottleDirection(myLocos[loco].cab)); } } break; case 'F': //F onOff function { bool onOff=aval[1]=='1'; int fKey = getInt(aval+2); LOOPLOCOS(throttleChar, cab) { DCC::setFn(myLocos[loco].cab, fKey,onOff); } } break; case 'q': if (aval[1]=='V') { //qV LOOPLOCOS(throttleChar, cab) { StringFormatter::send(stream,F("M%cA%c%d<;>V%d\n"), throttleChar, LorS(myLocos[loco].cab), myLocos[loco].cab, DCC::getThrottleSpeed(myLocos[loco].cab)); } } else if (aval[1]=='R') { // qR LOOPLOCOS(throttleChar, cab) { StringFormatter::send(stream,F("M%cA%c%d<;>R%d\n"), throttleChar, LorS(myLocos[loco].cab), myLocos[loco].cab, DCC::getThrottleDirection(myLocos[loco].cab)); } } break; case 'R': { bool forward=aval[1]!='0'; LOOPLOCOS(throttleChar, cab) { DCC::setThrottle(myLocos[loco].cab, DCC::getThrottleSpeed(myLocos[loco].cab), forward); } } break; case 'X': //Emergency Stop (speed code 1) LOOPLOCOS(throttleChar, cab) { DCC::setThrottle(myLocos[loco].cab,1, DCC::getThrottleDirection(myLocos[loco].cab)); } break; case 'I': // Idle case 'Q': // Quit LOOPLOCOS(throttleChar, cab) { DCC::setThrottle(myLocos[loco].cab,0, DCC::getThrottleDirection(myLocos[loco].cab)); } break; } } void WiThrottle::loop() { // for each WiThrottle, check the heartbeat for (WiThrottle* wt=firstThrottle; wt!=NULL ; wt=wt->nextThrottle) wt->checkHeartbeat(); } void WiThrottle::checkHeartbeat() { if(heartBeatEnable && (millis()-heartBeat > HEARTBEAT_TIMEOUT*1000)) { DIAG(F("WiThrottle hearbeat missed client=%d"),clientid); // Haertbeat missed... STOP all locos for this client for (int loco=0;loco