/// <summary>
/// Processes turns in a phase manner. After 10 calls to ProcessTurn
/// all 10 phases will be complete and the method will have completed
/// one game tick.
/// </summary>
/// <returns>True if a tick has been processed, false otherwise.</returns>
public Boolean ProcessTurn()
{
// shutdownError and invalidPeerError are two errors that get set from
// deep in the system. We process them here because it is a clean place
// to restart the game since we aren't in the middle of any phases.
// This is just a mechanism for cleanly throwing an error from a known good
// location.
if (_shutdownError)
{
_shutdownError = false;
throw new ShutdownFailureException();
}
if (_invalidPeerError)
{
_invalidPeerError = false;
throw new InvalidPeerException();
}
// We break the main processing of the game into 10 phases that have been tuned to each
// take roughly the same amount of time. We paint the screen in between each one. This way
// We can have a constant frame rate and incrementally do the engine processing we need to
// do.
// After we do all 10 phases we've done one game "tick". We can do two ticks a second which means
// we have a frame rate of 20.
switch (_turnPhase)
{
case 0:
// If we are in ecosystem mode, we want to save the game state periodically in case the user
// shuts down the screensaver by pressing ctl-alt-del which just kills the process. This way
// we won't have lost too much processing time.
// We always want to save on the tick after we've reported so we don't get our state messed up
// on the server. For example: never start the game in a state that was before the information
// was sent to the server because the server will think we're corrupted.
if (_logState ||
(_ecosystemMode && _populationData.IsReportingTick(CurrentVector.State.TickNumber - 1)))
{
Debug.WriteLine("Saving state.");
serializeState(_currentStateFileName);
}
// Give 1/5 of the animals a chance to do their processing
Scheduler.Tick();
break;
case 1:
// Give 1/5 of the animals a chance to do their processing
Scheduler.Tick();
break;
case 2:
// Give 1/5 of the animals a chance to do their processing
Scheduler.Tick();
break;
case 3:
// Give 1/5 of the animals a chance to do their processing
Scheduler.Tick();
break;
case 4:
// Give 1/5 of the animals a chance to do their processing
Scheduler.Tick();
break;
case 5:
// Get all the actions that the animals want to perform in this tick.
TickActions act = _scheduler.GatherTickActions();
CurrentVector.Actions = act;
// Create a mutable version of the world state that we'll change to create the next
// world state.
_newWorldState = (WorldState) CurrentVector.State.DuplicateMutable();
_newWorldState.TickNumber = _newWorldState.TickNumber + 1;
_populationData.BeginTick(_newWorldState.TickNumber, CurrentVector.State.StateGuid);
// Remove any organisms queued to be removed
removeOrganismsFromQueue();
// We take a snapshot of the organism IDs since we do several foreach loops
// and change the state, which causes exceptions to occur
_organismIDList = new string[_newWorldState.OrganismIDs.Count];
_newWorldState.OrganismIDs.CopyTo(_organismIDList, 0);
killDiseasedOrganisms2();
break;
case 6:
Debug.Assert(_newWorldState != null, "Worldstate did not get created for this tick");
// Do this first, since it always must happen so that things (like growing)
// won't happen if there isn't enough energy
burnBaseEnergy();
// Do attacks before movement so that when a carnivore asks if it can attack
// they actually get to hit the target before it moves
doAttacks();
doDefends();
changeMovementVectors();
break;
case 7:
moveAnimals();
break;
case 8:
doBites();
growAllOrganisms();
incubate();
startReproduction();
heal();
break;
case 9:
// Do this last so that the plant always starts charged up,
// and has to operate with what it has for the next turn
giveEnergyToPlants();
// Teleport after all actions have been processed so that there are
// no single turn pending actions left for the organism.
teleportOrganisms();
// Insert any new organisms
insertOrganismsFromQueue();
// Set Antenna States
doAntennas();
// We're done changing the state, now make it immutable
_newWorldState.MakeImmutable();
Debug.Assert(_newWorldState.Organisms.Count == Scheduler.Organisms.Count);
WorldVector vector = new WorldVector(_newWorldState);
CurrentVector = vector;
_scheduler.CurrentState = _newWorldState;
_populationData.EndTick(_newWorldState.TickNumber);
_newWorldState = null;
break;
}
_turnPhase++;
if (_turnPhase == 10)
{
_turnPhase = 0;
return true;
}
return false;
}
/// <summary>
/// Constructs a new game engine.
/// </summary>
/// <param name="dataPath">The path to save game directory.</param>
/// <param name="useNetwork">Controls the usage of the network engine.</param>
/// <param name="deserializeState">Controls if the state is deserialized or not.</param>
/// <param name="fileName">The path to the state file.</param>
/// <param name="reportData">Determines if data should be reported.</param>
/// <param name="leds">Provides a listing of game leds that can be used.</param>
/// <param name="trackLastRun">Controls whether the PAC keeps track of the last run creature for blacklisting.</param>
private GameEngine(string dataPath, bool useNetwork, bool deserializeState, string fileName, bool reportData,
TerrariumLed[] leds, bool trackLastRun)
{
_ledIndicators = leds;
_currentStateFileName = fileName;
// test to make sure we're not violating any constraints by current
// physics settings in the engine.
EngineSettings.EngineSettingsAsserts();
// Calculate quanta and worldsize if we haven't done so yet
if (_reloadSettings)
CalculateWorldSize();
_pac = new PrivateAssemblyCache(dataPath, fileName, true, trackLastRun);
// Reset the appdomain policy since we changed the location of the organism dlls
// This must be done before any animals are loaded in any way. Make sure this call stays
// as soon as possible
AppDomain.CurrentDomain.SetAppDomainPolicy(SecurityUtils.MakePolicyLevel(_pac.AssemblyDirectory));
_usingNetwork = useNetwork;
_populationData = new PopulationData(reportData, leds[(int) LedIndicators.ReportWebService]);
// Should only happen if an exception prevented a previous attempt to start a game
if (AppMgr.CurrentScheduler != null)
{
AppMgr.DestroyScheduler();
}
// Create a scheduler that manages giving the creatures timeslices
_scheduler = AppMgr.CreateSameDomainScheduler(this);
_scheduler.Quantum = _organismQuanta;
if (useNetwork)
{
// Required to start up the network listeners
_networkEngine = new NetworkEngine();
}
WorldState currentState;
Boolean successfulDeserialization = false;
if (deserializeState && File.Exists(fileName))
{
try
{
if (_pac.LastRun.Length != 0)
{
// The process was killed while an organism was being run, blacklist it
// Since this potentially means the animal hung the game.
_pac.BlacklistAssemblies(new string[] {_pac.LastRun});
}
this.deserializeState(fileName);
currentState = CurrentVector.State;
_scheduler.CurrentState = currentState;
_scheduler.CompleteOrganismDeserialization();
successfulDeserialization = true;
}
catch (Exception e)
{
ErrorLog.LogHandledException(e);
}
}
if (successfulDeserialization) return;
// Set up initial world state
currentState = new WorldState(GridWidth, GridHeight);
currentState.TickNumber = 0;
currentState.StateGuid = Guid.NewGuid();
currentState.Teleporter = new Teleporter(AnimalCount/EngineSettings.NumberOfAnimalsPerTeleporter);
currentState.MakeImmutable();
WorldVector vector = new WorldVector(currentState);
CurrentVector = vector;
_scheduler.CurrentState = currentState;
}