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CommandStation-EX/WiThrottle.cpp
Neil McKechnie fd36ca2b92 Restructure Turnout class.
Turnout class split into a base class for common code and specific subclasses for Servo, DCC, VPIN and LCN turnouts.
Interface further narrowed to reduce direct access to member variables.
Turnout creation command handling has been moved into the DCCEXParser class.
Turnout function and parameter names changed to make the Throw and Close functionality explicit.
Turnout commands <T id C> (close) and <T id T> (throw) added.
2021-08-19 21:22:59 +01:00

434 lines
19 KiB
C++

/*
* © 2020, Chris Harlow. All rights reserved.
* © 2020, Harald Barth
*
* 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 <https://www.gnu.org/licenses/>.
*/
/*
* 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
* implementation 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 <Arduino.h>
#include "defines.h"
#include "WiThrottle.h"
#include "DCC.h"
#include "DCCWaveform.h"
#include "StringFormatter.h"
#include "Turnouts.h"
#include "DIAG.h"
#include "GITHUB_SHA.h"
#include "version.h"
#include "RMFT2.h"
#define LOOPLOCOS(THROTTLECHAR, CAB) for (int loco=0;loco<MAX_MY_LOCO;loco++) \
if ((myLocos[loco].throttle==THROTTLECHAR || '*'==THROTTLECHAR) && (CAB<0 || myLocos[loco].cab==CAB))
WiThrottle * WiThrottle::firstThrottle=NULL;
WiThrottle* WiThrottle::getThrottle( int wifiClient) {
for (WiThrottle* wt=firstThrottle; wt!=NULL ; wt=wt->nextThrottle)
if (wt->clientid==wifiClient) return wt;
return new WiThrottle( wifiClient);
}
bool WiThrottle::isThrottleInUse(int cab) {
for (WiThrottle* wt=firstThrottle; wt!=NULL ; wt=wt->nextThrottle)
if (wt->areYouUsingThrottle(cab)) return true;
return false;
}
bool WiThrottle::areYouUsingThrottle(int cab) {
LOOPLOCOS('*', cab) { // see if I have this cab in use
return true;
}
return false;
}
// One instance of WiThrottle per connected client, so we know what the locos are
WiThrottle::WiThrottle( int wificlientid) {
if (Diag::WITHROTTLE) DIAG(F("%l Creating new WiThrottle for client %d"),millis(),wificlientid);
nextThrottle=firstThrottle;
firstThrottle= this;
clientid=wificlientid;
initSent=false; // prevent sending heartbeats before connection completed
heartBeatEnable=false; // until client turns it on
turnoutListHash = -1; // make sure turnout list is sent once
exRailSent=false;
mostRecentCab=0;
for (int loco=0;loco<MAX_MY_LOCO; loco++) myLocos[loco].throttle='\0';
}
WiThrottle::~WiThrottle() {
if (firstThrottle== this) {
firstThrottle=this->nextThrottle;
return;
}
for (WiThrottle* wt=firstThrottle; wt!=NULL ; wt=wt->nextThrottle) {
if (wt->nextThrottle==this) {
wt->nextThrottle=this->nextThrottle;
return;
}
}
}
void WiThrottle::parse(RingStream * stream, byte * cmdx) {
byte * cmd=cmdx;
heartBeat=millis();
if (Diag::WITHROTTLE) DIAG(F("%l WiThrottle(%d)<-[%e]"),millis(),clientid,cmd);
if (initSent) {
// Send power state if different than last sent
bool currentPowerState = (DCCWaveform::mainTrack.getPowerMode()==POWERMODE::ON);
if (lastPowerState != currentPowerState) {
StringFormatter::send(stream,F("PPA%x\n"),currentPowerState);
lastPowerState = currentPowerState;
}
// Send turnout list if changed since last sent (will replace list on client)
if (turnoutListHash != Turnout::turnoutlistHash) {
StringFormatter::send(stream,F("PTL"));
for(Turnout *tt=Turnout::first();tt!=NULL;tt=tt->next()){
int id=tt->getId();
StringFormatter::send(stream,F("]\\[%d}|{%d}|{%c"), id, id, Turnout::isClosed(id)?'2':'4');
}
StringFormatter::send(stream,F("\n"));
turnoutListHash = Turnout::turnoutlistHash; // keep a copy of hash for later comparison
}
else if (!exRailSent) {
// Send ExRail routes list if not already sent (but not at same time as turnouts above)
exRailSent=true;
#ifdef RMFT_ACTIVE
RMFT2::emitWithrottleRouteList(stream);
#endif
}
}
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);
if (MotorDriver::commonFaultPin) // commonFaultPin prevents individual track handling
DCCWaveform::progTrack.setPowerMode(cmd[3]=='1'?POWERMODE::ON:POWERMODE::OFF);
StringFormatter::send(stream,F("PPA%x\n"),DCCWaveform::mainTrack.getPowerMode()==POWERMODE::ON);
lastPowerState = (DCCWaveform::mainTrack.getPowerMode()==POWERMODE::ON); //remember power state sent for comparison later
}
#if defined(RMFT_ACTIVE)
else if (cmd[1]=='R' && cmd[2]=='A' && cmd[3]=='2' ) { // Route activate
// exrail routes are RA2Rn , Animations are RA2An
int route=getInt(cmd+5);
uint16_t cab=cmd[4]=='A' ? mostRecentCab : 0;
RMFT2::createNewTask(route, cab);
}
#endif
else if (cmd[1]=='T' && cmd[2]=='A') { // PTA accessory toggle
int id=getInt(cmd+4);
if (!Turnout::exists(id)) {
// If turnout does not exist, create it
int addr = ((id - 1) / 4) + 1;
int subaddr = (id - 1) % 4;
DCCTurnout::create(id,addr,subaddr);
StringFormatter::send(stream, F("HmTurnout %d created\n"),id);
}
switch (cmd[3]) {
// T and C according to RCN-213 where 0 is Stop, Red, Thrown, Diverging.
case 'T':
Turnout::setClosed(id,false);
break;
case 'C':
Turnout::setClosed(id,true);
break;
case '2':
Turnout::setClosed(id,!Turnout::isClosed(id));
break;
default :
Turnout::setClosed(id,true);
break;
}
StringFormatter::send(stream, F("PTA%c%d\n"),Turnout::isClosed(id)?'2':'4',id );
}
break;
case 'N': // Heartbeat (2), only send if connection completed by 'HU' message
if (initSent) {
StringFormatter::send(stream, F("*%d\n"),HEARTBEAT_SECONDS); // return timeout value
}
break;
case 'M': // multithrottle
multithrottle(stream, cmd);
break;
case 'H': // send initial connection info after receiving "HU" message
if (cmd[1] == 'U') {
StringFormatter::send(stream,F("VN2.0\nHTDCC-EX\nRL0\n"));
StringFormatter::send(stream,F("HtDCC-EX v%S, %S, %S, %S\n"), F(VERSION), F(ARDUINO_TYPE), DCC::getMotorShieldName(), F(GITHUB_SHA));
StringFormatter::send(stream,F("PTT]\\[Turnouts}|{Turnout]\\[THROW}|{2]\\[CLOSE}|{4\n"));
StringFormatter::send(stream,F("PPA%x\n"),DCCWaveform::mainTrack.getPowerMode()==POWERMODE::ON);
lastPowerState = (DCCWaveform::mainTrack.getPowerMode()==POWERMODE::ON); //remember power state sent for comparison later
StringFormatter::send(stream,F("*%d\n"),HEARTBEAT_SECONDS);
initSent = true;
}
break;
case 'Q': //
LOOPLOCOS('*', -1) { // tell client to drop any locos still assigned to this WiThrottle
if (myLocos[loco].throttle!='\0') {
StringFormatter::send(stream, F("M%c-%c%d<;>\n"), myLocos[loco].throttle, LorS(myLocos[loco].cab), myLocos[loco].cab);
}
}
if (Diag::WITHROTTLE) DIAG(F("%l WiThrottle(%d) Quit"),millis(),clientid);
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(RingStream * 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("Multithrottle aval=%c cab=%d"), aval[0],locoid);
switch(cmd[2]) {
case '+': // add loco request
if (cmd[3]=='*') {
// M+* means get loco from prog track, then join tracks ready to drive away
// Stash the things the callback will need later
stashStream= stream;
stashClient=stream->peekTargetMark();
stashThrottleChar=throttleChar;
stashInstance=this;
// ask DCC to call us back when the loco id has been read
DCC::getLocoId(getLocoCallback); // will remove any previous join
return; // return nothing in stream as response is sent later in the callback
}
//return error if address zero requested
if (locoid==0) {
StringFormatter::send(stream, F("HMAddress '0' not supported!\n"), cmd[3] ,locoid);
return;
}
//return error if L or S from request doesn't match DCC++ assumptions
if (cmd[3] != LorS(locoid)) {
StringFormatter::send(stream, F("HMLength '%c' not valid for %d!\n"), cmd[3] ,locoid);
return;
}
//use first empty "slot" on this client's list, will be added to DCC registration list
for (int loco=0;loco<MAX_MY_LOCO;loco++) {
if (myLocos[loco].throttle=='\0') {
myLocos[loco].throttle=throttleChar;
myLocos[loco].cab=locoid;
mostRecentCab=locoid;
StringFormatter::send(stream, F("M%c+%c%d<;>\n"), throttleChar, cmd[3] ,locoid); //tell client to add loco
//Get known Fn states from DCC
for(int fKey=0; fKey<=28; fKey++) {
int fstate=DCC::getFn(locoid,fKey);
if (fstate>=0) StringFormatter::send(stream,F("M%cA%c%d<;>F%d%d\n"),throttleChar,cmd[3],locoid,fstate,fKey);
}
StringFormatter::send(stream, F("M%cA%c%d<;>V%d\n"), throttleChar, cmd[3], locoid, DCCToWiTSpeed(DCC::getThrottleSpeed(locoid)));
StringFormatter::send(stream, F("M%cA%c%d<;>R%d\n"), throttleChar, cmd[3], locoid, DCC::getThrottleDirection(locoid));
StringFormatter::send(stream, F("M%cA%c%d<;>s1\n"), throttleChar, cmd[3], locoid); //default speed step 128
return;
}
}
StringFormatter::send(stream, F("HMMax locos (%d) exceeded, %d not added!\n"), MAX_MY_LOCO ,locoid);
break;
case '-': // remove loco(s) from this client (leave in DCC registration)
LOOPLOCOS(throttleChar, locoid) {
myLocos[loco].throttle='\0';
StringFormatter::send(stream, F("M%c-%c%d<;>\n"), throttleChar, LorS(myLocos[loco].cab), myLocos[loco].cab);
}
break;
case 'A':
locoAction(stream,aval, throttleChar, locoid);
}
}
void WiThrottle::locoAction(RingStream * stream, byte* aval, char throttleChar, int cab){
// Note cab=-1 for all cabs in the consist called throttleChar.
// DIAG(F("Loco Action aval=%c%c throttleChar=%c, cab=%d"), aval[0],aval[1],throttleChar, cab);
switch (aval[0]) {
case 'V': // Vspeed
{
int witSpeed=getInt(aval+1);
LOOPLOCOS(throttleChar, cab) {
mostRecentCab=myLocos[loco].cab;
DCC::setThrottle(myLocos[loco].cab, WiTToDCCSpeed(witSpeed), DCC::getThrottleDirection(myLocos[loco].cab));
StringFormatter::send(stream,F("M%cA%c%d<;>V%d\n"), throttleChar, LorS(myLocos[loco].cab), myLocos[loco].cab, witSpeed);
}
}
break;
case 'F': //F onOff function
{
bool funcstate;
bool pressed=aval[1]=='1';
int fKey = getInt(aval+2);
LOOPLOCOS(throttleChar, cab) {
funcstate = DCC::changeFn(myLocos[loco].cab, fKey, pressed);
if(funcstate==0 || funcstate==1)
StringFormatter::send(stream,F("M%cA%c%d<;>F%d%d\n"), throttleChar, LorS(myLocos[loco].cab),
myLocos[loco].cab, funcstate, fKey);
}
}
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, DCCToWiTSpeed(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) {
mostRecentCab=myLocos[loco].cab;
DCC::setThrottle(myLocos[loco].cab, DCC::getThrottleSpeed(myLocos[loco].cab), forward);
StringFormatter::send(stream,F("M%cA%c%d<;>R%d\n"), throttleChar, LorS(myLocos[loco].cab), 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));
StringFormatter::send(stream,F("M%cA%c%d<;>V%d\n"), throttleChar, LorS(myLocos[loco].cab), myLocos[loco].cab, -1);
}
break;
case 'I': // Idle, set speed to 0
case 'Q': // Quit, set speed to 0
LOOPLOCOS(throttleChar, cab) {
mostRecentCab=myLocos[loco].cab;
DCC::setThrottle(myLocos[loco].cab, 0, DCC::getThrottleDirection(myLocos[loco].cab));
StringFormatter::send(stream,F("M%cA%c%d<;>V%d\n"), throttleChar, LorS(myLocos[loco].cab), myLocos[loco].cab, 0);
}
break;
}
}
// convert between DCC++ speed values and WiThrottle speed values
int WiThrottle::DCCToWiTSpeed(int DCCSpeed) {
if (DCCSpeed == 0) return 0; //stop is stop
if (DCCSpeed == 1) return -1; //eStop value
return DCCSpeed - 1; //offset others by 1
}
// convert between WiThrottle speed values and DCC++ speed values
int WiThrottle::WiTToDCCSpeed(int WiTSpeed) {
if (WiTSpeed == 0) return 0; //stop is stop
if (WiTSpeed == -1) return 1; //eStop value
return WiTSpeed + 1; //offset others by 1
}
void WiThrottle::loop(RingStream * stream) {
// for each WiThrottle, check the heartbeat
for (WiThrottle* wt=firstThrottle; wt!=NULL ; wt=wt->nextThrottle)
wt->checkHeartbeat();
// TODO... any broadcasts to be done
(void)stream;
/* MUST follow this model in this loop.
* stream->mark();
* send 1 digit client id, and any data
* stream->commit()
*/
}
void WiThrottle::checkHeartbeat() {
// if eStop time passed... eStop any locos still assigned to this client and then drop the connection
if(heartBeatEnable && (millis()-heartBeat > ESTOP_SECONDS*1000)) {
if (Diag::WITHROTTLE) DIAG(F("%l WiThrottle(%d) eStop(%ds) timeout, drop connection"), millis(), clientid, ESTOP_SECONDS);
LOOPLOCOS('*', -1) {
if (myLocos[loco].throttle!='\0') {
if (Diag::WITHROTTLE) DIAG(F("%l eStopping cab %d"),millis(),myLocos[loco].cab);
DCC::setThrottle(myLocos[loco].cab, 1, DCC::getThrottleDirection(myLocos[loco].cab)); // speed 1 is eStop
}
}
delete this;
}
}
char WiThrottle::LorS(int cab) {
return (cab<127)?'S':'L';
}
// Drive Away feature. Callback handling
RingStream * WiThrottle::stashStream;
WiThrottle * WiThrottle::stashInstance;
byte WiThrottle::stashClient;
char WiThrottle::stashThrottleChar;
void WiThrottle::getLocoCallback(int16_t locoid) {
stashStream->mark(stashClient);
if (locoid<0) StringFormatter::send(stashStream,F("HMNo loco found on prog track\n"));
else {
char addcmd[20]={'M',stashThrottleChar,'+',LorS(locoid) };
itoa(locoid,addcmd+4,10);
stashInstance->multithrottle(stashStream, (byte *)addcmd);
DCCWaveform::progTrack.setPowerMode(POWERMODE::ON);
DCC::setProgTrackSyncMain(true); // <1 JOIN> so we can drive loco away
}
stashStream->commit();
}