internal static void update(ElapseData data)
{
currentTime = data.TotalTime.Seconds;
if (ScheduleResetTimer)
{
ResetTimerMethod();
ScheduleResetTimer = false;
}
if (DSDDisableOnTrainStop && data.Vehicle.Speed.KilometersPerHour < 1)
{
ResetTimerMethod();
}
if (DSDTimerBrakeExceeded)
{
if (data.Vehicle.Speed.KilometersPerHour > 1)
{
data.Handles.PowerNotch = 0;
data.Handles.BrakeNotch = SafetySystem.BrakeNotches + 1;
}
else
{
DSDTimerBrakeExceeded = false;
}
}
if (DSDTimerTimeout != 0 && DSDTimer > DSDTimerTimeout)
{
if (DSDTimer < DSDTimerBrakeTimeout)
{
SoundManager.Play(ATSSoundManager.DSDTimerExceeded, 1.0, 1.0, true);
}
else if (DSDTimer > DSDTimerBrakeTimeout)
{
if (DSDTimerBrakeTimeout != DSDTimerTimeout)
{
DSDTimerBrakeExceeded = true;
}
SoundManager.Stop(ATSSoundManager.DSDTimerExceeded);
SoundManager.Play(ATSSoundManager.DSDTimerBrake, 1.0, 1.0, true);
}
}
else
{
DSDTimerExceeded = false;
SoundManager.Stop(ATSSoundManager.DSDTimerExceeded);
SoundManager.Stop(ATSSoundManager.DSDTimerBrake);
}
DSDTimer = data.TotalTime.Seconds - DSDLastTimer;
}
/// <summary>Call this function from the traction manager to attempt to reset a Vigilante intervention</summary>
internal void VigilanteReset()
{
if (Train.CurrentSpeed == 0 && VigilanteState == VigilanteStates.EbApplied)
{
if (SCMT.tpwswarningsound != -1)
{
SoundManager.Stop(SCMT.tpwswarningsound);
}
Train.TractionManager.ResetBrakeApplication();
SCMT.spiarossi_act = false;
VigilanteState = VigilanteStates.None;
}
}
/// <summary>This function is called from the traction manager when the TPWS reset key is pressed.</summary>
internal void tpwsresetkey()
{
if (trainstop == true && this.Enabled == true)
{
if (flagbrake == true)
{
SetIndicator(ref TraintripIndicator, 1);
SetIndicator(ref BrakeDemandIndicator, 1);
Train.TractionManager.ResetBrakeApplication();
//Something is a little funnny here
//This would appear to reset the lights instantly?
SetIndicator(ref TraintripIndicator, 0);
SetIndicator(ref BrakeDemandIndicator, 0);
if (beacon_type == 44003)
{
beacon_type = 44004;
}
if (tpwswarningsound != -1)
{
SoundManager.Stop(tpwswarningsound);
}
flagbrake = false;
flagriarmo = false;
SpiaRossiTimer.TimerActive = false;
spiarossi_act = false;
//flagspiarossi = false; ???
}
else
{
SetIndicator(ref BrakeDemandIndicator, 1);
if (flagriarmo == true)
{
flagriarmo = false;
Train.TractionManager.ResetBrakeApplication();
SetIndicator(ref BrakeDemandIndicator, 0);
trainstop = false;
if (beacon_type == 44003)
{
beacon_type = 44004;
}
if (tpwswarningsound != -1)
{
SoundManager.Stop(tpwswarningsound);
}
SpiaRossiTimer.TimerActive = false;
spiarossi_act = false;
}
}
}
}
/// <summary>Is called every frame.</summary>
/// <param name="data">The data.</param>
/// <param name="blocking">Whether the device is blocked or will block subsequent devices.</param>
internal override void Elapse(ElapseData data, ref bool blocking)
{
if (this.Enabled)
{
CurrentVehicleState = data.Vehicle;
if (NextSignalLocation < double.MaxValue)
{
double distance = NextSignalLocation - data.Vehicle.Location;
if (distance < 350.0)
{
if (NextSignalAspect < CurrentAspect)
{
AcknowledgementCountdown = 7.0;
}
else if (NextSignalAspect > CurrentAspect && EBApplied != false)
{
if (UpgradeSound != -1)
{
SoundManager.Play(UpgradeSound, 1.0, 1.0, false);
}
}
CurrentAspect = NextSignalAspect;
NextSignalLocation = double.MaxValue;
}
}
if (data.ElapsedTime.Seconds > 0.0 & data.ElapsedTime.Seconds < 1.0)
{
if (EmergencyBrakeCountdown > 0.0)
{
EmergencyBrakeCountdown -= data.ElapsedTime.Seconds;
if (EmergencyBrakeCountdown < 0.0)
{
EBApplied = false;
CurrentAspect = PendingAspect;
EmergencyBrakeCountdown = 0.0;
AcknowledgementCountdown = 0.0;
Train.TractionManager.ResetBrakeApplication();
}
else
{
EBApplied = true;
Train.TractionManager.DemandBrakeApplication(this.Train.Specs.BrakeNotches + 1, "Brake application demanded by the CAWS system");
}
}
else if (AcknowledgementCountdown > 0.0)
{
AcknowledgementPending = true;
AcknowledgementCountdown -= data.ElapsedTime.Seconds;
if (AcknowledgementCountdown < 0.0)
{
AcknowledgementCountdown = 0.0;
EmergencyBrakeCountdown = 60.0;
AcknowledgementPending = false;
}
}
}
//Panel Indicators
if (AspectIndicator != -1)
{
this.Train.Panel[AspectIndicator] = CurrentAspect;
if (EBApplied == true)
{
this.Train.Panel[AspectIndicator] = 0;
}
}
if (AcknowlegementIndicator != -1)
{
if (AcknowledgementPending == true)
{
this.Train.Panel[AcknowlegementIndicator] = 1;
}
else
{
this.Train.Panel[AcknowlegementIndicator] = 0;
}
}
if (EBIndicator != -1)
{
if (EBApplied == true)
{
this.Train.Panel[EBIndicator] = 1;
}
else
{
this.Train.Panel[EBIndicator] = 0;
}
}
//Sounds
if (DowngradeSound != -1)
{
if (AcknowledgementPending == true)
{
SoundManager.Play(DowngradeSound, 1.0, 1.0, true);
}
else
{
SoundManager.Stop(DowngradeSound);
}
}
}
}
/// <summary>Is called every frame.</summary>
/// <param name="data">The data.</param>
/// <param name="blocking">Whether the device is blocked or will block subsequent devices.</param>
internal override void Elapse(ElapseData data, ref bool blocking)
{
//Required to reset the max notch before each frame
this.Train.TractionManager.SetMaxPowerNotch(this.Train.Specs.PowerNotches, false);
//If reverser is put into neutral when moving, block the gears
if (reversercontrol != 0 && Train.CurrentSpeed > 0 && Train.Handles.Reverser == 0)
{
Train.DieselEngine.gearsblocked = true;
}
if (!nogears)
{
//Set gear ratio for current gear
if (CurrentGear == 0)
{
gearratio = 0;
}
else if (CurrentGear <= geararray.Length)
{
gearratio = geararray[CurrentGear - 1];
}
else
{
gearratio = geararray[geararray.Length - 1];
}
//Set fade in ratio for current gear
if (CurrentGear == 0)
{
fadeinratio = 0;
}
else if (CurrentGear <= gearfadeinarray.Length)
{
fadeinratio = gearfadeinarray[CurrentGear - 1];
}
else
{
fadeinratio = gearfadeinarray[gearfadeinarray.Length - 1];
}
//Set fade out ratio for current gear
if (CurrentGear == 0)
{
fadeoutratio = 0;
}
else if (CurrentGear >= gearfadeoutarray.Length)
{
fadeoutratio = gearfadeoutarray[CurrentGear - 1];
}
else
{
fadeoutratio = gearfadeoutarray[gearfadeoutarray.Length - 1];
}
//If the fade in and fade out ratios would make this gear not work, set them both to zero
if (fadeinratio + fadeoutratio >= 1000)
{
fadeinratio = 0;
fadeoutratio = 0;
}
//Set current revolutions per minute
currentrevs = Math.Max(0, Math.Min(1000, Train.CurrentSpeed * gearratio));
//Now calculate the maximumum power notch
int power_limit;
if (currentrevs < fadeinratio)
{
power_limit = (int)((float)currentrevs / fadeinratio * this.Train.Specs.PowerNotches);
}
else if (currentrevs > 1000 - fadeoutratio)
{
power_limit = (int)(this.Train.Specs.PowerNotches - (float)(currentrevs - (1000 - fadeoutratio)) / fadeoutratio * this.Train.Specs.PowerNotches);
}
else
{
power_limit = this.Train.Specs.PowerNotches;
}
//Next we need to set the gears
//Manual gears are handled in the KeyUp function
//Automatic gears are handled here
if (this.Train.TractionManager.AutomaticAdvancedFunctions == true)
{
if (Train.DieselEngine.gearsblocked == true)
{
power_limit = 0;
//Stop, drop to N with no power applied and the gears will unblock
if (Train.CurrentSpeed == 0 && Train.Handles.Reverser == 0 && Train.Handles.PowerNotch == 0)
{
Train.DieselEngine.gearsblocked = false;
}
}
//Test if all handles are in a position for a gear to be activated
if (Train.Handles.Reverser != 0 && Train.Handles.PowerNotch != 0 && Train.Handles.BrakeNotch == 0)
{
gearplayed = false;
//If we aren't in gear & gears aren't blocked
if (CurrentGear == 0 && Train.DieselEngine.gearsblocked == false)
{
CurrentGear = 1;
gearchange();
Train.DieselEngine.gearloop = false;
Train.DieselEngine.gearlooptimer = 0.0;
}
if (currentrevs > Math.Min((2000 - fadeoutratio) / 2, 800) && CurrentGear < totalgears - 1)
{
CurrentGear++;
gearchange();
Train.DieselEngine.gearloop = false;
Train.DieselEngine.gearlooptimer = 0.0;
}
//Change down
else if (currentrevs < Math.Max(fadeinratio / 2, 200) && CurrentGear > 1)
{
CurrentGear--;
gearchange();
Train.DieselEngine.gearloop = false;
Train.DieselEngine.gearlooptimer = 0.0;
}
}
//If we're stopped with the power off, drop out of gear
else if (Train.Handles.Reverser == 0 && Train.Handles.PowerNotch == 0)
{
CurrentGear = 0;
if (gearplayed == false)
{
gearchange();
gearplayed = true;
}
}
}
//Finally set the power notch
if (CurrentGear != 0)
{
this.Train.TractionManager.SetMaxPowerNotch(Math.Min(power_limit, this.Train.Handles.PowerNotch), false);
//data.Handles.PowerNotch = Math.Min(power_limit, this.Train.Handles.PowerNotch);
}
else
{
this.Train.TractionManager.SetMaxPowerNotch(0, false);
}
//If revving the engine is allowed in neutral
if (allowneutralrevs == 1 && (CurrentGear == 0 || Train.Handles.Reverser == 0))
{
currentrevs = (int)Math.Abs((1000 / Train.Specs.PowerNotches) * Train.Handles.PowerNotch * 0.9);
//Play sounds based upon revs state
if (revsupsound != -1 && revsdownsound != -1 && motorsound != -1)
{
double pitch = (double)Train.Handles.PowerNotch / (double)Train.Specs.PowerNotches;
if (currentrevs > 0 && currentrevs > previousrevs)
{
SoundManager.Play(motorsound, 0.8, pitch, true);
SoundManager.Play(revsupsound, 1.0, 1.0, false);
SoundManager.Stop(revsdownsound);
}
else if (currentrevs >= 0 && currentrevs < previousrevs)
{
SoundManager.Play(motorsound, 0.8, pitch, true);
SoundManager.Play(revsdownsound, 1.0, 1.0, false);
SoundManager.Stop(revsupsound);
}
else if (currentrevs == 0)
{
SoundManager.Stop(revsupsound);
SoundManager.Stop(revsdownsound);
SoundManager.Stop(motorsound);
}
previousrevs = currentrevs;
}
}
//Check we've got a maximum temperature and a heating part
if (overheat != 0 && heatingpart != 0)
{
this.heatingtimer += data.ElapsedTime.Milliseconds;
if (heatingpart == 0 | overheat == 0)
{
//No heating part or overheat temperature not set
this.temperature = 0.0;
this.heatingtimer = 0.0;
}
else if (heatingpart == 1)
{
//Heats based upon power notch
if (this.heatingtimer > 1000)
{
this.heatingtimer = 0.0;
if (Train.Handles.PowerNotch == 0)
{
currentheat = heatingarray[0];
}
else if (Train.Handles.PowerNotch < heatingarray.Length)
{
currentheat = heatingarray[Train.Handles.PowerNotch];
}
else
{
currentheat = heatingarray[heatingarray.Length - 1];
}
temperature += currentheat;
}
}
else
{
//Heats based upon RPM
int revspercentage = currentrevs / 100;
if (this.heatingtimer > 1000)
{
this.heatingtimer = 0.0;
if (revspercentage == 0)
{
currentheat = heatingarray[0];
}
else if (revspercentage < heatingarray.Length)
{
currentheat = heatingarray[revspercentage];
}
else
{
currentheat = heatingarray[heatingarray.Length - 1];
}
temperature += currentheat;
}
}
//Keep temperature below max & above zero
if (temperature > overheat)
{
temperature = overheat;
if (overheatresult == 1 && Train.TractionManager.EngineOverheated == false)
{
Train.TractionManager.DemandPowerCutoff("Power cutoff was demanded due to the diesel engine overheating");
Train.TractionManager.EngineOverheated = true;
}
}
else if (temperature < overheat && temperature > 0)
{
Train.TractionManager.ResetPowerCutoff();
Train.TractionManager.EngineOverheated = false;
}
else if (temperature < 0)
{
temperature = 0;
}
}
}
//This section of code uses fuel
fuelusetimer += data.ElapsedTime.Milliseconds;
if (fuelusetimer > 1000)
{
fuelusetimer = 0.0;
if (data.Handles.PowerNotch < fuelarray.Length)
{
fuel -= fuelarray[data.Handles.PowerNotch];
}
else
{
fuel -= fuelarray[fuelarray.Length - 1];
}
if (fuel <= 0)
{
fuel = 0;
}
}
//This section of code fills our fuel tanks
if (fuelling == true)
{
fuellingtimer += data.ElapsedTime.Milliseconds;
if (fuellingtimer > 1000)
{
fuellingtimer = 0.0;
fuel += (int)fuelfillspeed;
}
if (fuel > fuelcapacity)
{
fuel = (int)fuelcapacity;
}
}
//This section of code runs the gear loop sound
if (gearloopsound != -1 && CurrentGear != 0)
{
//Start the timer
gearlooptimer += data.ElapsedTime.Milliseconds;
if (gearlooptimer > gearlooptime && gearloop == false)
{
//Start playback and reset our conditions
gearloop = true;
SoundManager.Play(gearloopsound, 1.0, 1.0, true);
}
else if (gearloop == false)
{
SoundManager.Stop(gearloopsound);
}
}
else if (gearloopsound != -1 && CurrentGear == 0)
{
SoundManager.Stop(gearloopsound);
}
{
//Panel Variables
//Ammeter
if (Ammeter.PanelIndex != -1)
{
if (Train.TractionManager.PowerCutoffDemanded == true)
{
this.Train.Panel[Ammeter.PanelIndex] = 0;
}
else
{
this.Train.Panel[Ammeter.PanelIndex] = Ammeter.GetCurrentValue();
}
}
if (!nogears)
{
if (gearindicator != -1)
{
this.Train.Panel[(gearindicator)] = CurrentGear;
}
if (tachometer != -1)
{
this.Train.Panel[(tachometer)] = currentrevs;
}
}
if (automaticindicator != -1)
{
if (this.Train.TractionManager.AutomaticAdvancedFunctions == false)
{
this.Train.Panel[(automaticindicator)] = 0;
}
else
{
this.Train.Panel[(automaticindicator)] = 1;
}
}
if (thermometer != -1)
{
this.Train.Panel[(thermometer)] = (int)temperature;
}
if (overheatindicator != -1)
{
if (temperature > overheatwarn)
{
this.Train.Panel[(overheatindicator)] = 1;
}
else
{
this.Train.Panel[(overheatindicator)] = 0;
}
}
if (fuelindicator != -1)
{
this.Train.Panel[(fuelindicator)] = fuel;
}
if (fuelfillindicator != -1)
{
if (fuelling == true)
{
this.Train.Panel[(fuelfillindicator)] = 1;
}
}
}
{
//Sounds
if (overheatalarm != -1)
{
if (temperature > overheatwarn)
{
SoundManager.Play(overheatalarm, 1.0, 1.0, true);
}
else
{
SoundManager.Stop(overheatalarm);
}
}
}
}
/// <summary>Is called every frame.</summary>
/// <param name="data">The data.</param>
/// <param name="blocking">Whether the device is blocked or will block subsequent devices.</param>
internal override void Elapse(ElapseData data, ref bool blocking)
{
OverspeedDevice.Update(data.ElapsedTime.Milliseconds);
{
//Deadman's Handle
if (deadmanshandle != 0)
{
//Initialise and set the start state
if (Train.StartupSelfTestManager != null &&
Train.StartupSelfTestManager.SequenceState != StartupSelfTestManager.SequenceStates.Initialised)
{
//Startup self-test has not been performed, no systems active
DeadmansHandleState = DeadmanStates.None;
}
else if (Train.ElectricEngine != null && Train.ElectricEngine.FrontPantograph.State != PantographStates.OnService &&
Train.ElectricEngine.RearPantograph.State != PantographStates.OnService && Train.CurrentSpeed == 0)
{
//Stationary with no available pantographs
DeadmansHandleState = DeadmanStates.None;
}
else if (vigilanceinactivespeed == -2 && Train.Handles.Reverser == 0)
{
//Set to no action if inactive speed is -2 & in neutral
DeadmansHandleState = DeadmanStates.None;
}
else if (vigilanceinactivespeed == -2 && Train.Handles.Reverser != 0)
{
//Otherwise set to the timer state
DeadmansHandleState = DeadmanStates.OnTimer;
}
else if (vigilanceinactivespeed == -1)
{
//If inactive speed is -1 always set to the timer state
DeadmansHandleState = DeadmanStates.OnTimer;
}
else if (Train.CurrentSpeed < vigilanceinactivespeed && DeadmansHandleState == DeadmanStates.OnTimer)
{
//If train speed is than the inactive speed and we're in the timer mode
//Set to no action
DeadmansHandleState = DeadmanStates.None;
}
else if (Train.CurrentSpeed > vigilanceinactivespeed && DeadmansHandleState == DeadmanStates.None)
{
//Set to the timer state
DeadmansHandleState = DeadmanStates.OnTimer;
}
//Calculate vigilance time from the array
int vigilancelength = vigilancearray.Length;
if (Train.Handles.PowerNotch == 0)
{
vigilancetime = vigilancearray[0];
}
else if (Train.Handles.PowerNotch <= vigilancelength)
{
vigilancetime = vigilancearray[(Train.Handles.PowerNotch - 1)];
}
else
{
vigilancetime = vigilancearray[(vigilancelength - 1)];
}
if (DeadmansHandleState == DeadmanStates.OnTimer)
{
//Reset other timers
deadmansalarmtimer = 0.0;
deadmansbraketimer = 0.0;
//Elapse Timer
this.deadmanstimer += data.ElapsedTime.Milliseconds;
if (this.deadmanstimer > vigilancetime)
{
DeadmansHandleState = DeadmanStates.TimerExpired;
}
}
else if (DeadmansHandleState == DeadmanStates.TimerExpired)
{
//Start the next timer
deadmansalarmtimer += data.ElapsedTime.Milliseconds;
if (deadmansalarmtimer > vigilancedelay1)
{
DeadmansHandleState = DeadmanStates.OnAlarm;
}
}
else if (DeadmansHandleState == DeadmanStates.OnAlarm)
{
//Trigger the alarm sound and move on
if (vigilancealarm != -1)
{
SoundManager.Play(vigilancealarm, 1.0, 1.0, true);
}
DeadmansHandleState = DeadmanStates.AlarmTimer;
}
else if (DeadmansHandleState == DeadmanStates.AlarmTimer)
{
//Start the next timer
deadmansbraketimer += data.ElapsedTime.Milliseconds;
if (deadmansbraketimer > vigilancedelay2)
{
DeadmansHandleState = DeadmanStates.BrakesApplied;
}
}
else if (DeadmansHandleState == DeadmanStates.BrakesApplied)
{
//Demand brake application
Train.TractionManager.DemandBrakeApplication(this.Train.Specs.BrakeNotches + 1, "Brake application demanded by the deadman's handle");
//If we auto-release on coming to a full-stop
if (AutoRelease == true && Train.CurrentSpeed == 0)
{
Train.TractionManager.ResetBrakeApplication();
deadmansalarmtimer = 0.0;
deadmansbraketimer = 0.0;
deadmanstimer = 0.0;
DeadmansHandleState = DeadmanStates.OnTimer;
}
}
}
}
if (Train.SCMT != null)
{
if (vigilanteEnabled == true && SCMT.testscmt == 4)
{
if (Train.CurrentSpeed > 2 && VigilanteState == VigilanteStates.None)
{
VigilanteState = VigilanteStates.AlarmSounding;
}
else if (VigilanteState == VigilanteStates.AlarmSounding)
{
if (vigilancealarm != -1)
{
SoundManager.Play(vigilancealarm, 1.0, 1.0, true);
}
if (Train.CurrentSpeed != 0)
{
vigilanteTimer += data.ElapsedTime.Milliseconds;
if (vigilanteTimer > vigilancedelay1)
{
VigilanteState = VigilanteStates.EbApplied;
}
}
}
else if (VigilanteState == VigilanteStates.EbApplied)
{
vigilanteTimer = 0.0;
Train.TractionManager.DemandBrakeApplication(this.Train.Specs.BrakeNotches + 1, "Brake application demanded by the SCMT vigilante");
if (vigilancealarm != -1)
{
SoundManager.Stop(vigilancealarm);
}
if (SCMT.tpwswarningsound != -1)
{
SoundManager.Play(SCMT.tpwswarningsound, 1.0, 1.0, true);
}
}
else if (VigilanteState == VigilanteStates.OnService)
{
vigilanteTimer = 0.0;
if (Train.CurrentSpeed == 0)
{
VigilanteState = VigilanteStates.None;
}
}
}
}
{
//Set Panel Variables
if (DRAIndicator != -1)
{
if (Train.drastate == true)
{
this.Train.Panel[(DRAIndicator)] = 1;
}
else
{
this.Train.Panel[(DRAIndicator)] = 0;
}
}
if (vigilancelamp != -1)
{
if (DeadmansHandleState == DeadmanStates.None || DeadmansHandleState == DeadmanStates.OnTimer)
{
this.Train.Panel[(vigilancelamp)] = 0;
}
else
{
this.Train.Panel[(vigilancelamp)] = 1;
}
if (vigilanteEnabled == true)
{
if (VigilanteState == VigilanteStates.AlarmSounding || VigilanteState == VigilanteStates.EbApplied)
{
this.Train.Panel[(vigilancelamp)] = 1;
}
else
{
this.Train.Panel[(vigilancelamp)] = 0;
}
}
}
}
}
internal static void PlayLoop(VirtualKeys key)
{
VirtualKeys virtualKey = key;
switch (virtualKey)
{
case VirtualKeys.S:
if (SoundManager.IsPlaying(Keysloop[10]))
{
SoundManager.Stop(Keysloop[10]);
}
else
{
SoundManager.Play(Keysloop[10], 1.0, 1.0, true);
}
break;
case VirtualKeys.A1:
if (SoundManager.IsPlaying(Keysloop[37]))
{
SoundManager.Stop(Keysloop[37]);
}
else
{
SoundManager.Play(Keysloop[37], 1.0, 1.0, true);
}
break;
case VirtualKeys.A2:
if (SoundManager.IsPlaying(Keysloop[36]))
{
SoundManager.Stop(Keysloop[36]);
}
else
{
SoundManager.Play(Keysloop[36], 1.0, 1.0, true);
}
break;
case VirtualKeys.B1:
if (SoundManager.IsPlaying(Keysloop[35]))
{
SoundManager.Stop(Keysloop[35]);
}
else
{
SoundManager.Play(Keysloop[35], 1.0, 1.0, true);
}
break;
case VirtualKeys.B2:
if (SoundManager.IsPlaying(Keysloop[34]))
{
SoundManager.Stop(Keysloop[34]);
}
else
{
SoundManager.Play(Keysloop[34], 1.0, 1.0, true);
}
break;
case VirtualKeys.C1:
if (SoundManager.IsPlaying(Keysloop[33]))
{
SoundManager.Stop(Keysloop[33]);
}
else
{
SoundManager.Play(Keysloop[33], 1.0, 1.0, true);
}
break;
case VirtualKeys.C2:
if (SoundManager.IsPlaying(Keysloop[32]))
{
SoundManager.Stop(Keysloop[32]);
}
else
{
SoundManager.Play(Keysloop[32], 1.0, 1.0, true);
}
break;
case VirtualKeys.D:
if (SoundManager.IsPlaying(Keysloop[2]))
{
SoundManager.Stop(Keysloop[2]);
}
else
{
SoundManager.Play(Keysloop[2], 1.0, 1.0, true);
}
break;
case VirtualKeys.E:
if (SoundManager.IsPlaying(Keysloop[3]))
{
SoundManager.Stop(Keysloop[3]);
}
else
{
SoundManager.Play(Keysloop[3], 1.0, 1.0, true);
}
break;
case VirtualKeys.F:
if (SoundManager.IsPlaying(Keysloop[4]))
{
SoundManager.Stop(Keysloop[4]);
}
else
{
SoundManager.Play(Keysloop[4], 1.0, 1.0, true);
}
break;
case VirtualKeys.G:
if (SoundManager.IsPlaying(Keysloop[5]))
{
SoundManager.Stop(Keysloop[5]);
}
else
{
SoundManager.Play(Keysloop[5], 1.0, 1.0, true);
}
break;
case VirtualKeys.H:
if (SoundManager.IsPlaying(Keysloop[6]))
{
SoundManager.Stop(Keysloop[6]);
}
else
{
SoundManager.Play(Keysloop[6], 1.0, 1.0, true);
}
break;
case VirtualKeys.I:
if (SoundManager.IsPlaying(Keysloop[7]))
{
SoundManager.Stop(Keysloop[7]);
}
else
{
SoundManager.Play(Keysloop[7], 1.0, 1.0, true);
}
break;
case VirtualKeys.J:
if (SoundManager.IsPlaying(Keysloop[8]))
{
SoundManager.Stop(Keysloop[8]);
}
else
{
SoundManager.Play(Keysloop[8], 1.0, 1.0, true);
}
break;
case VirtualKeys.K:
if (SoundManager.IsPlaying(Keysloop[9]))
{
SoundManager.Stop(Keysloop[9]);
}
else
{
SoundManager.Play(Keysloop[9], 1.0, 1.0, true);
}
break;
case VirtualKeys.L:
if (SoundManager.IsPlaying(Keysloop[0]))
{
SoundManager.Stop(Keysloop[0]);
}
else
{
SoundManager.Play(Keysloop[0], 1.0, 1.0, true);
}
break;
case VirtualKeys.EngineStart:
if (SoundManager.IsPlaying(Keysloop[31]))
{
SoundManager.Stop(Keysloop[31]);
}
else
{
SoundManager.Play(Keysloop[31], 1.0, 1.0, true);
}
break;
case VirtualKeys.EngineStop:
if (SoundManager.IsPlaying(Keysloop[30]))
{
SoundManager.Stop(Keysloop[30]);
}
else
{
SoundManager.Play(Keysloop[30], 1.0, 1.0, true);
}
break;
case VirtualKeys.Blowers:
if (SoundManager.IsPlaying(Keysloop[29]))
{
SoundManager.Stop(Keysloop[29]);
}
else
{
SoundManager.Play(Keysloop[29], 1.0, 1.0, true);
}
break;
case VirtualKeys.ExhaustSteamInjector:
if (SoundManager.IsPlaying(Keysloop[28]))
{
SoundManager.Stop(Keysloop[28]);
}
else
{
SoundManager.Play(Keysloop[28], 1.0, 1.0, true);
}
break;
case VirtualKeys.IncreaseCutoff:
if (SoundManager.IsPlaying(Keysloop[27]))
{
SoundManager.Stop(Keysloop[27]);
}
else
{
SoundManager.Play(Keysloop[27], 1.0, 1.0, true);
}
break;
case VirtualKeys.DecreaseCutoff:
if (SoundManager.IsPlaying(Keysloop[26]))
{
SoundManager.Stop(Keysloop[26]);
}
else
{
SoundManager.Play(Keysloop[26], 1.0, 1.0, true);
}
break;
case VirtualKeys.FillFuel:
if (SoundManager.IsPlaying(Keysloop[25]))
{
SoundManager.Stop(Keysloop[25]);
}
else
{
SoundManager.Play(Keysloop[25], 1.0, 1.0, true);
}
break;
case VirtualKeys.GearDown:
if (SoundManager.IsPlaying(Keysloop[24]))
{
SoundManager.Stop(Keysloop[24]);
}
else
{
SoundManager.Play(Keysloop[24], 1.0, 1.0, true);
}
break;
case VirtualKeys.GearUp:
if (SoundManager.IsPlaying(Keysloop[23]))
{
SoundManager.Stop(Keysloop[23]);
}
else
{
SoundManager.Play(Keysloop[23], 1.0, 1.0, true);
}
break;
case VirtualKeys.LeftDoors:
if (SoundManager.IsPlaying(Keysloop[22]))
{
SoundManager.Stop(Keysloop[22]);
}
else
{
SoundManager.Play(Keysloop[22], 1.0, 1.0, true);
}
break;
case VirtualKeys.RightDoors:
if (SoundManager.IsPlaying(Keysloop[21]))
{
SoundManager.Stop(Keysloop[21]);
}
else
{
SoundManager.Play(Keysloop[21], 1.0, 1.0, true);
}
break;
case VirtualKeys.LiveSteamInjector:
if (SoundManager.IsPlaying(Keysloop[20]))
{
SoundManager.Stop(Keysloop[20]);
}
else
{
SoundManager.Play(Keysloop[20], 1.0, 1.0, true);
}
break;
case VirtualKeys.LowerPantograph:
if (SoundManager.IsPlaying(Keysloop[19]))
{
SoundManager.Stop(Keysloop[19]);
}
else
{
SoundManager.Play(Keysloop[19], 1.0, 1.0, true);
}
break;
case VirtualKeys.RaisePantograph:
if (SoundManager.IsPlaying(Keysloop[18]))
{
SoundManager.Stop(Keysloop[18]);
}
else
{
SoundManager.Play(Keysloop[18], 1.0, 1.0, true);
}
break;
case VirtualKeys.MainBreaker:
if (SoundManager.IsPlaying(Keysloop[17]))
{
SoundManager.Stop(Keysloop[17]);
}
else
{
SoundManager.Play(Keysloop[17], 1.0, 1.0, true);
}
break;
case VirtualKeys.WiperSpeedDown:
if (SoundManager.IsPlaying(Keysloop[16]))
{
SoundManager.Stop(Keysloop[20]);
}
else
{
SoundManager.Play(Keysloop[16], 1.0, 1.0, true);
}
break;
case VirtualKeys.WiperSpeedUp:
if (SoundManager.IsPlaying(Keysloop[15]))
{
SoundManager.Stop(Keysloop[20]);
}
else
{
SoundManager.Play(Keysloop[15], 1.0, 1.0, true);
}
break;
default:
break;
}
}
/// <summary>Is called every frame.</summary>
/// <param name="data">The data.</param>
/// <param name="blocking">Whether the device is blocked or will block subsequent devices.</param>
internal override void Elapse(ElapseData data, ref bool blocking)
{
//The Western requires special handling- Return if AWS has not been switched in from the cab
if (Train.WesternDiesel != null && Train.AWS.Enabled == false)
{
if (Train.WesternDiesel.StartupManager.StartupState == WesternStartupManager.SequenceStates.AWSOnline)
{
//Enable AWS if the Western has switched it online
Train.AWS.Enabled = true;
}
else
{
//Otherwise, we don't want to do any processing so back out
//Doing anything else messes up the timing of the self-test sequence
return;
}
}
if (MySequenceState == SequenceStates.Pending)
{
Train.MasterSwitch = false;
Train.selftest = false;
/* Check the reverser state to see if the master switch has been set to on */
if (Train.Handles.Reverser == 1 || Train.Handles.Reverser == -1)
{
MySequenceState = SequenceStates.WaitingToStart;
}
}
else if (MySequenceState == SequenceStates.WaitingToStart)
{
if (Train.Handles.Reverser == 0)
{
/* Turn the master switch on, and begin the startup and self-test procedure */
Train.selftest = true;
Train.MasterSwitch = true;
MySequenceState = SequenceStates.Initialising;
/* Start the in-cab blower */
// if (PowerSupplyManager.SelectedPowerSupply != Plugin.MainBattery) {
// Plugin.Fan.Reset();
// }
/* Place the Automatic Warning System, and Train Protection and Warning System, into self-test mode */
Train.AWS.SelfTest();
Train.TPWS.SelfTest();
}
}
else if (MySequenceState != SequenceStates.Initialised)
{
/* Make sure that the master switch is on after reinitialisation */
Train.selftest = true;
Train.MasterSwitch = true;
/* Hold the brakes on until the AWS button is depressed */
if (MySequenceState == SequenceStates.AwaitingDriverInteraction)
{
Train.TractionManager.DemandBrakeApplication(this.Train.Specs.BrakeNotches, "Brake application was demanded by the startup self-test sequence");
}
else if (MySequenceState == SequenceStates.Finalising)
{
if (Train.AWS.WarningSound != -1)
{
if (SoundManager.IsPlaying(Train.AWS.WarningSound))
{
SoundManager.Stop(Train.AWS.WarningSound);
}
}
MySequenceState = SequenceStates.Initialised;
Train.TractionManager.ResetBrakeApplication();
}
/* Lastly, decrement the timer */
if (MySequenceState == SequenceStates.Initialising)
{
MySequenceTimer = MySequenceTimer - (int)data.ElapsedTime.Milliseconds;
if (MySequenceTimer < 0)
{
MySequenceTimer = 0;
MySequenceState = SequenceStates.AwaitingDriverInteraction;
}
}
}
else
{
if (this.firststart == false)
{
this.firststart = true;
if (Train.AWS.Enabled == true)
{
Train.AWS.OnStartUp(SunflowerState);
}
if (Train.TPWS.Enabled)
{
Train.TPWS.Initialize(InitializationModes.OnService);
}
}
}
}
internal override void KeyDown(VirtualKeys key)
{
if (key == Train.CurrentKeyConfiguration.AWSKey)
{
awsKeyPressed = true;
if (tpwsStartupTest == 2)
{
awsIndicatorLit = true;
SoundManager.Stop(awsWarningSound);
if (startupTest == 2)
{
SoundManager.Stop(awsClearSound);
brakeDemandIndicatorLit = false;
stopOverrideIndicatorLit = false;
tpwsIndicator3Lit = false;
}
tpwsStartupTest = 0;
}
else if (awsTimer.TimerActive && awsTimer.TimeElapsed != -2)
{
awsIndicatorLit = true;
SoundManager.Stop(awsWarningSound);
awsTimer.TimerActive = false;
}
else if (awsTimer.TimeElapsed != -2 && (Train.CurrentSpeed == 0 || awsBrakeCancel != 0) && awsStop)
{
if (awsBrakeCancel == 1)
{
awsRelease = true;
}
else
{
Train.TractionManager.DemandBrakeApplication(Train.Specs.BrakeNotches + 1, "Brake application demanded by the LU Trainstop system self-test.");
awsIndicatorLit = false;
SoundManager.Stop(awsWarningSound);
awsTimer.TimerActive = false;
awsStop = false;
}
}
if (key == Train.CurrentKeyConfiguration.SafetyKey && tpwsTrainstop)
{
brakeDemandIndicatorLit = true;
if (tpwsBrakeCancel != 0 || (Train.CurrentSpeed == 0 && stopTimer.TimeElapsed > tpwsStopDelay * 1000))
{
if (tpwsBrakeCancel == 1)
{
tpwsRelease = true;
}
else
{
Train.TractionManager.DemandBrakeApplication(Train.Specs.BrakeNotches + 1, "EB Brake application demanded by the LU Trainstop system.");
brakeDemandIndicatorLit = false;
tpwsTrainstop = false;
}
SoundManager.Stop(tpwsWarningSound);
}
}
if (key == Train.CurrentKeyConfiguration.TPWSOverride && tpwsTrainstop == false && tpwsStartupTest == 0)
{
if (overrideTimer.TimerActive == false)
{
overrideTimer.TimeElapsed = 0;
//BlinkIndicator(stopOverride, 1);
}
else
{
overrideTimer.TimerActive = false;
stopOverrideIndicatorLit = false;
}
}
}
}
/// <summary>Is called every frame.</summary>
/// <param name="data">The data.</param>
/// <param name="blocking">Whether the device is blocked or will block subsequent devices.</param>
internal override void Elapse(ElapseData data, ref bool blocking)
{
{
if (TripcockActive == true)
{
if (DeadmansDeviceActive == true)
{
//We can accelerate!
//If the throttle button is held down, then the train will accelerate towards the selected speed
switch (CurrentSpeed)
{
case SelectorSpeeds.B25:
data.Handles.Reverser = -1;
if (Train.CurrentSpeed < 25 && Train.TractionManager.PowerCutoffDemanded == false)
{
data.Handles.PowerNotch = Train.Specs.PowerNotches;
}
else
{
data.Handles.PowerNotch = 0;
}
break;
case SelectorSpeeds.B15:
data.Handles.Reverser = -1;
if (Train.CurrentSpeed < 15 && Train.TractionManager.PowerCutoffDemanded == false)
{
data.Handles.PowerNotch = Train.Specs.PowerNotches;
}
else
{
data.Handles.PowerNotch = 0;
}
break;
case SelectorSpeeds.Neutral:
data.Handles.Reverser = 0;
data.Handles.PowerNotch = 0;
break;
case SelectorSpeeds.F15:
data.Handles.Reverser = 1;
if (Train.CurrentSpeed < 15 && Train.TractionManager.PowerCutoffDemanded == false)
{
data.Handles.PowerNotch = Train.Specs.PowerNotches;
}
else
{
data.Handles.PowerNotch = 0;
}
break;
case SelectorSpeeds.F25:
data.Handles.Reverser = 1;
if (Train.CurrentSpeed < 25 && Train.TractionManager.PowerCutoffDemanded == false)
{
data.Handles.PowerNotch = Train.Specs.PowerNotches;
}
else
{
data.Handles.PowerNotch = 0;
}
break;
case SelectorSpeeds.F50:
data.Handles.Reverser = 1;
if (Train.CurrentSpeed < 50 && Train.TractionManager.PowerCutoffDemanded == false)
{
data.Handles.PowerNotch = Train.Specs.PowerNotches;
}
else
{
data.Handles.PowerNotch = 0;
}
break;
case SelectorSpeeds.F60:
data.Handles.Reverser = 1;
if (Train.CurrentSpeed < 60 && Train.TractionManager.PowerCutoffDemanded == false)
{
data.Handles.PowerNotch = Train.Specs.PowerNotches;
}
else
{
data.Handles.PowerNotch = 0;
}
break;
case SelectorSpeeds.F70:
data.Handles.Reverser = 1;
if (Train.CurrentSpeed < 70 && Train.TractionManager.PowerCutoffDemanded == false)
{
data.Handles.PowerNotch = Train.Specs.PowerNotches;
}
else
{
data.Handles.PowerNotch = 0;
}
break;
}
}
else
{
//The F92 has a counter for unwanted EB applications
if (Train.TractionManager.BrakeInterventionDemanded == false)
{
EmergencyBrakeCounter++;
}
//If deadman's device is inactive, apply EB
Train.TractionManager.DemandBrakeApplication(Train.Specs.BrakeNotches + 1, "Brake application demanded by the F92");
}
}
else
{
//If our tripcock is not currently turned on, then power must be cut off
Train.TractionManager.DemandPowerCutoff("Power cutoff demanded by the F92 tripcock");
}
//Max speed device
if (Train.CurrentSpeed > 70 && Overspeed == false)
{
//I'm presuming that the overspeed device will also up the EB counter, need to check this....
EmergencyBrakeCounter++;
Train.TractionManager.DemandBrakeApplication(Train.Specs.BrakeNotches, "Brake application demanded by the F92 overspeed device");
SoundManager.Play(OverspeedSound, 1.0, 1.0, true);
Overspeed = true;
}
else
{
if (Overspeed == true)
{
//Only attempt to reset the brake application once, else this causes log spam
Train.TractionManager.ResetBrakeApplication();
SoundManager.Stop(OverspeedSound);
Overspeed = false;
}
}
}
//Sounds
{
//If our trainspeed is greater than 50km/h then we should play the curve flange sound
if (Train.CurrentSpeed > 50 && CurveFlangeNoise == true)
{
//Requires fade-in sound
SoundManager.Play(CurveFlangeSound, 1.0, 1.0, true);
}
else
{
SoundManager.Stop(CurveFlangeSound);
//Requires fade-out sound
}
//This sound is played whilst in tight curves (Rumbling noise) whilst the speed is above 25km/h
if (Train.CurrentSpeed > 25 && TightCurveNoise == true)
{
//Requires fade-in sound
SoundManager.Play(TightCurveSound, 1.0, 1.0, true);
}
else
{
//Requires fade-out sound
SoundManager.Stop(CurveFlangeSound);
}
}
}
/// <summary>Is called every frame.</summary>
/// <param name="data">The data.</param>
/// <param name="blocking">Whether the device is blocked or will block subsequent devices.</param>
internal override void Elapse(ElapseData data, ref bool blocking)
{
if (this.Enabled)
{
if (this.SafetyState != SafetyStates.Isolated)
{
if (this.suppressionactive)
{
/* Cancel any suppression which is in effect, if the train is not within range of the last suppression magnet location */
if (Train.CurrentSpeed > 0)
{
if (Train.TrainLocation > this.suppressionlocation + 2)
{
this.suppressionlocation = 0;
this.suppressionactive = false;
}
}
else
{
if (Train.TrainLocation < this.suppressionlocation - 2)
{
this.suppressionlocation = 0;
this.suppressionactive = false;
}
}
}
else if (this.MySafetyState == SafetyStates.Primed)
{
/* An AWS magnet south pole has primed the AWS */
this.SunflowerState = SunflowerStates.Clear;
this.detectiontimer = this.detectiontimer + (int)data.ElapsedTime.Milliseconds;
if (this.detectiontimer > 1000)
{
/* No north pole has been detected within the timeout period, so reset the detection timer and issue an AWS warning */
this.detectiontimer = 0;
this.MySafetyState = SafetyStates.CancelTimerActive;
}
}
else if (this.MySafetyState == SafetyStates.Clear)
{
/* The AWS indicates a clear signal */
this.Reset();
this.SunflowerState = SunflowerStates.Clear;
if (this.ClearSound != -1)
{
SoundManager.Play(ClearSound, 1.0, 1.0, false);
}
if (this.WarningSound != -1)
{
SoundManager.Stop(WarningSound);
}
}
else if (this.MySafetyState == SafetyStates.CancelTimerActive)
{
/* An AWS warning has been issued */
if (this.WarningSound != -1)
{
SoundManager.Play(WarningSound, 1.0, 1.0, true);
}
this.SunflowerState = SunflowerStates.Clear;
this.canceltimer -= (int)data.ElapsedTime.Milliseconds;
if (this.canceltimer < 0)
{
this.canceltimer = 0;
this.MySafetyState = SafetyStates.CancelTimerExpired;
}
}
else if (this.MySafetyState == SafetyStates.WarningAcknowledged)
{
/* An AWS warning was acknowledged in time */
if (this.WarningSound != -1)
{
SoundManager.Stop(WarningSound);
}
this.Reset();
}
else if (this.MySafetyState == SafetyStates.CancelTimerExpired)
{
/* An AWS warning was not acknowledged in time */
if (this.WarningSound != -1)
{
SoundManager.Play(WarningSound, 1.0, 1.0, true);
}
if (Train.TPWS.Enabled)
{
Train.TPWS.IssueBrakeDemand();
}
else
{
if (Train.TractionManager.PowerCutoffDemanded == false)
{
Train.TractionManager.DemandPowerCutoff("Power cutoff was demanded by the AWS due to a warning not being acknowledged in time");
}
if (Train.TractionManager.CurrentInterventionBrakeNotch != this.Train.Specs.BrakeNotches + 1)
{
Train.TractionManager.DemandBrakeApplication(this.Train.Specs.BrakeNotches + 1, "Emergency brakes were demanded by the AWS due to a warning not being acknowledged in time");
}
}
}
else if (this.MySafetyState == SafetyStates.SelfTest)
{
blinktimer += (int)data.ElapsedTime.Milliseconds;
if (blinktimer > 1200)
{
if (Train.AWS.WarningSound != -1)
{
if (startuphorntriggered == false)
{
SoundManager.Play(WarningSound, 1.0, 1.0, true);
startuphorntriggered = true;
}
}
}
else if (blinktimer > 1000)
{
this.SunflowerState = SunflowerStates.Clear;
}
else if (blinktimer > 400)
{
this.SunflowerState = SunflowerStates.Warn;
}
}
else if (this.MySafetyState == SafetyStates.TPWSAWSBrakeDemandIssued)
{
/* The TPWS issued an AWS Brake Demand due to the AWS not being acknowledged in time */
if (TPWSWarningSound != -1)
{
SoundManager.Play(TPWSWarningSound, 1.0, 1.0, true);
}
}
}
else if (this.SafetyState == SafetyStates.Isolated)
{
if (WarningSound != -1)
{
if (SoundManager.IsPlaying(WarningSound))
{
SoundManager.Stop(WarningSound);
}
}
if (TPWSWarningSound != -1)
{
if (SoundManager.IsPlaying(TPWSWarningSound))
{
SoundManager.Stop(TPWSWarningSound);
}
}
this.canceltimer = (int)this.canceltimeout;
this.SunflowerState = SunflowerStates.Warn;
}
/* Set the state of the AWS Sunflower instrument */
if (awsindicator != -1)
{
if (this.SunflowerState == SunflowerStates.Warn)
{
this.Train.Panel[awsindicator] = 1;
}
else
{
this.Train.Panel[awsindicator] = 0;
}
}
}
//Set the state of the cancel button panel index
//As this is a physical button, it can be pressed at any time
if (CancelButtonIndex != -1)
{
if (CancelButtonPressed)
{
this.Train.Panel[CancelButtonIndex] = 1;
}
else
{
this.Train.Panel[CancelButtonIndex] = 0;
}
}
}
/// <summary>Is called every frame.</summary>
/// <param name="data">The data.</param>
/// <param name="blocking">Whether the device is blocked or will block subsequent devices.</param>
internal override void Elapse(ElapseData data, ref bool blocking)
{
//Required to reset the max notch before each frame
this.Train.TractionManager.SetMaxPowerNotch(this.Train.Specs.PowerNotches, false);
//Check we've got a maximum temperature and a heating part
if (overheat != 0 && heatingpart != 0)
{
this.heatingtimer += data.ElapsedTime.Milliseconds;
if (heatingpart == 0 || overheat == 0)
{
//No heating part or overheat temperature not set
this.temperature = 0.0;
this.heatingtimer = 0.0;
}
else if (heatingpart == 1)
{
//Heats based upon power notch
if (this.heatingtimer > 1000)
{
this.heatingtimer = 0.0;
if (Train.Handles.PowerNotch == 0)
{
currentheat = HeatingRates[0];
}
else if (Train.Handles.PowerNotch < HeatingRates.Length)
{
currentheat = HeatingRates[Train.Handles.PowerNotch];
}
else
{
currentheat = HeatingRates[HeatingRates.Length - 1];
}
temperature += currentheat;
}
}
else
{
//Heats based upon RPM- Not on an electric loco!
this.temperature = 0.0;
this.heatingtimer = 0.0;
}
//Keep temperature below max & above zero
if (temperature > overheat)
{
temperature = overheat;
if (overheatresult == 1 && Train.TractionManager.EngineOverheated == false)
{
DemandPowerCutoff("Power cutoff was demanded due to the electric engine overheating");
Train.TractionManager.EngineOverheated = true;
}
}
else if (temperature < overheat && temperature > 0)
{
if (BreakerTripped == false && ((FrontPantograph.State == PantographStates.Disabled && RearPantograph.State == PantographStates.OnService) ||
(RearPantograph.State == PantographStates.Disabled && FrontPantograph.State == PantographStates.OnService)))
{
ResetPowerCutoff("Power cutoff was released due to the electric engine temperature returning to safe levels");
}
Train.TractionManager.EngineOverheated = false;
}
else if (temperature < 0)
{
temperature = 0;
}
}
{
//If we're in a power gap, check whether we have a pickup available
if (PowerGap)
{
int new_power;
//First check to see whether the first pickup is in the neutral section
if (Train.TrainLocation - PickupLocations[0] > firstmagnet && Train.TrainLocation - PickupLocations[0] < nextmagnet)
{
//Cycle through the other pickups
int j = 0;
foreach (int t in PickupLocations)
{
if (Train.TrainLocation - t < firstmagnet)
{
j++;
}
}
switch (PowerGapBehaviour)
{
case PowerGapBehaviour.ProportionalReduction:
//Reduce max throttle by percentage of how many pickups are in the gap
double throttlemultiplier = (double)j / (double)PickupLocations.Length;
new_power = (int)(this.Train.Specs.PowerNotches * throttlemultiplier);
this.Train.TractionManager.SetMaxPowerNotch(new_power, false);
//data.Handles.PowerNotch = new_power;
break;
case PowerGapBehaviour.InactiveAny:
//Kill traction power if any pickup is on the gap
if (j != 0 && Train.TractionManager.PowerCutoffDemanded == false)
{
DemandPowerCutoff("Power cutoff was demanded due to a neutral gap in the overhead line");
}
break;
case PowerGapBehaviour.InactiveAll:
if (j == PickupLocations.Length && Train.TractionManager.PowerCutoffDemanded == false)
{
DemandPowerCutoff("Power cutoff was demanded due to a neutral gap in the overhead line");
}
break;
}
}
//Now, check to see if the last pickup is in the neutral section
else if (Train.TrainLocation - PickupLocations[PickupLocations.Length - 1] > firstmagnet && Train.TrainLocation - PickupLocations[PickupLocations.Length - 1] < nextmagnet)
{
//Cycle through the other pickups
int j = 0;
foreach (int t in PickupLocations)
{
if (Train.TrainLocation - t < firstmagnet)
{
j++;
}
}
switch (PowerGapBehaviour)
{
case PowerGapBehaviour.ProportionalReduction:
//Reduce max throttle by percentage of how many pickups are in the gap
double throttlemultiplier = (double)j / (double)PickupLocations.Length;
new_power = (int)(this.Train.Specs.PowerNotches * throttlemultiplier);
this.Train.TractionManager.SetMaxPowerNotch(new_power, false);
//data.Handles.PowerNotch = new_power;
break;
case PowerGapBehaviour.InactiveAny:
//Kill traction power if any pickup is on the gap
if (j != 0 && Train.TractionManager.PowerCutoffDemanded == false)
{
DemandPowerCutoff("Power cutoff was demanded due to a neutral gap in the overhead line");
}
break;
case PowerGapBehaviour.InactiveAll:
//Kill traction power when all pickups are on the gap
if (j == PickupLocations.Length && Train.TractionManager.PowerCutoffDemanded == false)
{
DemandPowerCutoff("Power cutoff was demanded due to a neutral gap in the overhead line");
}
break;
}
}
//Neither the first or last pickups are in the power gap, reset the power
//However also check that the breaker has not been tripped by a UKTrainSys beacon
else if (nextmagnet != 0 && (Train.TrainLocation - PickupLocations[PickupLocations.Length - 1]) > nextmagnet && (Train.TrainLocation - PickupLocations[0]) > nextmagnet)
{
PowerGap = false;
if (LegacyPowerCut == true)
{
//Reset legacy power cutoff state and retrip breaker
Train.ElectricEngine.TripBreaker();
LegacyPowerCut = false;
}
if (BreakerTripped == false && ((FrontPantograph.State == PantographStates.Disabled && RearPantograph.State == PantographStates.OnService) || (RearPantograph.State == PantographStates.Disabled && FrontPantograph.State == PantographStates.OnService)))
{
ResetPowerCutoff("Power cutoff was released due to leaving the neutral gap");
}
}
//If the final pickup has passed the UKTrainSys standard power gap location
else if (Train.TrainLocation - PickupLocations[PickupLocations.Length - 1] < lastmagnet)
{
PowerGap = false;
}
}
//This section of code handles a UKTrainSys compatible ACB/VCB
//
//If the ACB/VCB has tripped, always demand power cutoff
if (BreakerTripped == true && Train.TractionManager.PowerCutoffDemanded == false)
{
DemandPowerCutoff("Power cutoff was demanded due to the ACB/VCB state");
}
//If we're in a power gap, also always demand power cutoff
else if (BreakerTripped == false && PowerGap == true && Train.TractionManager.PowerCutoffDemanded == false)
{
DemandPowerCutoff("Power cutoff was demanded due to a neutral gap in the overhead line");
}
//If the ACB/VCB has now been reset with a pantograph available & we're not in a powergap reset traction power
if (BreakerTripped == false && PowerGap == false && (FrontPantograph.State == PantographStates.OnService || RearPantograph.State == PantographStates.OnService))
{
ResetPowerCutoff("Power cutoff was released due to the availability of overhead power");
}
}
{
//This section of code handles raising the pantographs and the alarm state
//
//If both pantographs are lowered or disabled, then there are no line volts
if ((FrontPantograph.State == PantographStates.Lowered || FrontPantograph.State == PantographStates.Disabled) &&
(RearPantograph.State == PantographStates.Lowered || RearPantograph.State == PantographStates.Disabled) && Train.TractionManager.PowerCutoffDemanded == false)
{
DemandPowerCutoff("Power cutoff was demanded due to no available pantographs");
PowerGap = true;
}
//If the powergap behaviour cuts power when *any* pantograph is disabled / lowered
//
//Line volts is lit, but power is still cut off
else if (FrontPantograph.State != PantographStates.Disabled && RearPantograph.State != PantographStates.Disabled &&
(FrontPantograph.State != PantographStates.OnService || RearPantograph.State != PantographStates.OnService) && PowerGapBehaviour == PowerGapBehaviour.InactiveAny && Train.TractionManager.PowerCutoffDemanded == false)
{
DemandPowerCutoff("Power cutoff was demanded due to no available pantographs");
}
//Pantographs
//One pantograph has been raised, and the line volts indicator has lit, but the timer is active
//Power cutoff is still in force
FrontPantograph.Update(data.ElapsedTime.Milliseconds);
RearPantograph.Update(data.ElapsedTime.Milliseconds);
if ((FrontPantograph.State == PantographStates.RaisedTimer && RearPantograph.State != PantographStates.OnService) || (RearPantograph.State == PantographStates.RaisedTimer && FrontPantograph.State != PantographStates.OnService))
{
PowerGap = false;
DemandPowerCutoff(null);
}
if (Train.CurrentSpeed > AutomaticPantographLowerSpeed)
{
//Automatic pantograph lowering
switch (PantographLoweringMode)
{
case AutomaticPantographLoweringModes.LowerAll:
//In lower all mode, we don't need to check anything
if (FrontPantograph.State == PantographStates.OnService || FrontPantograph.State == PantographStates.RaisedTimer || FrontPantograph.State == PantographStates.VCBReady)
{
FrontPantograph.Lower(true);
}
if (RearPantograph.State == PantographStates.OnService || RearPantograph.State == PantographStates.RaisedTimer || RearPantograph.State == PantographStates.VCBReady)
{
RearPantograph.Lower(true);
}
Train.DebugLogger.LogMessage("Automatically lowered all pantographs due to reaching the setspeed.");
break;
case AutomaticPantographLoweringModes.LowerFront:
if (RearPantograph.State == PantographStates.OnService)
{
if (FrontPantograph.State == PantographStates.OnService || FrontPantograph.State == PantographStates.RaisedTimer || FrontPantograph.State == PantographStates.VCBReady)
{
FrontPantograph.Lower(true);
Train.DebugLogger.LogMessage("Automatically lowered the front pantograph due to reaching the setspeed.");
}
}
break;
case AutomaticPantographLoweringModes.LowerRear:
if (FrontPantograph.State == PantographStates.OnService)
{
if (RearPantograph.State == PantographStates.OnService || RearPantograph.State == PantographStates.RaisedTimer || RearPantograph.State == PantographStates.VCBReady)
{
RearPantograph.Lower(true);
Train.DebugLogger.LogMessage("Automatically lowered the rear pantograph due to reaching the setspeed.");
}
}
break;
case AutomaticPantographLoweringModes.LowerFrontRegardless:
if (FrontPantograph.State == PantographStates.OnService || FrontPantograph.State == PantographStates.RaisedTimer || FrontPantograph.State == PantographStates.VCBReady)
{
FrontPantograph.Lower(true);
Train.DebugLogger.LogMessage("Automatically lowered the front pantograph due to reaching the setspeed.");
}
break;
case AutomaticPantographLoweringModes.LowerRearRegardless:
if (RearPantograph.State == PantographStates.OnService || RearPantograph.State == PantographStates.RaisedTimer || RearPantograph.State == PantographStates.VCBReady)
{
RearPantograph.Lower(true);
Train.DebugLogger.LogMessage("Automatically lowered the rear pantograph due to reaching the setspeed.");
}
break;
}
}
}
//This section of code runs the power notch loop sound
if (powerloopsound != -1 && data.Handles.PowerNotch != 0)
{
if (BreakerTripped == false)
{
//Start the timer
powerlooptimer += data.ElapsedTime.Milliseconds;
if (powerlooptimer > powerlooptime && powerloop == false)
{
//Start playback and reset our conditions
powerloop = true;
SoundManager.Play(powerloopsound, 1.0, 1.0, true);
}
else if (powerloop == false)
{
SoundManager.Stop(powerloopsound);
}
}
else
{
SoundManager.Stop(powerloopsound);
}
}
else if (powerloopsound != -1 && this.Train.Handles.PowerNotch == 0)
{
SoundManager.Stop(powerloopsound);
}
//This section of code runs the breaker loop sound
if (breakerloopsound != -1 && BreakerTripped == false)
{
if (!PowerGap && SoundManager.IsPlaying(breakerloopsound) == false)
{
breakerlooptimer += data.ElapsedTime.Milliseconds;
if (breakerlooptimer > breakerlooptime)
{
SoundManager.Play(breakerloopsound, 1.0, 1.0, true);
breakerlooptimer = 0.0;
}
}
}
else if (breakerloopsound != -1 && BreakerTripped == true)
{
SoundManager.Stop(breakerloopsound);
breakerlooptimer = 0.0;
}
//Panel Indicies
{
//Ammeter
if (Ammeter.PanelIndex != -1)
{
if (PowerGap == true || BreakerTripped == true || Train.TractionManager.PowerCutoffDemanded == true)
{
this.Train.Panel[Ammeter.PanelIndex] = 0;
}
else
{
this.Train.Panel[Ammeter.PanelIndex] = Ammeter.GetCurrentValue();
}
}
//Line Volts indicator
if (powerindicator != -1)
{
if (!PowerGap)
{
this.Train.Panel[powerindicator] = 1;
}
else
{
this.Train.Panel[powerindicator] = 0;
}
}
//ACB/VCB Breaker Indicator
if (breakerindicator != -1)
{
if (!BreakerTripped)
{
this.Train.Panel[breakerindicator] = 1;
}
else
{
this.Train.Panel[breakerindicator] = 0;
}
}
if (thermometer != -1)
{
this.Train.Panel[(thermometer)] = (int)temperature;
}
if (overheatindicator != -1)
{
if (temperature > overheatwarn)
{
this.Train.Panel[(overheatindicator)] = 1;
}
else
{
this.Train.Panel[(overheatindicator)] = 0;
}
}
//Pantograph Indicators
if (FrontPantograph.PanelIndex != -1)
{
if (FrontPantograph.Raised() == true)
{
this.Train.Panel[FrontPantograph.PanelIndex] = 1;
}
else
{
this.Train.Panel[FrontPantograph.PanelIndex] = 0;
}
}
if (RearPantograph.PanelIndex != -1)
{
if (RearPantograph.Raised() == true)
{
this.Train.Panel[RearPantograph.PanelIndex] = 1;
}
else
{
this.Train.Panel[RearPantograph.PanelIndex] = 0;
}
}
}
//Sounds
{
if (overheatalarm != -1)
{
if (temperature > overheatalarm)
{
SoundManager.Play(overheatalarm, 1.0, 1.0, true);
}
else
{
SoundManager.Stop(overheatalarm);
}
}
}
//Pass information to the advanced driving window
if (AdvancedDriving.CheckInst != null)
{
TractionManager.debuginformation[14] = Convert.ToString(FrontPantograph.State);
TractionManager.debuginformation[15] = Convert.ToString(RearPantograph.State);
TractionManager.debuginformation[16] = Convert.ToString(!BreakerTripped);
TractionManager.debuginformation[17] = Convert.ToString(!PowerGap);
}
}
