Ejemplo n.º 1
0
 // return read-only list of greenhouses in a vessel
 public static List<Greenhouse> GetGreenhouses(Vessel v)
 {
   if (v.loaded) return v.FindPartModulesImplementing<Greenhouse>();
   else
   {
     List<Greenhouse> ret = new List<Greenhouse>();
     foreach(ProtoPartSnapshot part in v.protoVessel.protoPartSnapshots)
     {
       foreach(ProtoPartModuleSnapshot module in part.modules)
       {
         if (module.moduleName == "Greenhouse")
         {
           Greenhouse greenhouse = new Greenhouse();
           greenhouse.ec_rate = Lib.GetProtoValue<double>(module, "ec_rate");
           greenhouse.waste_rate = Lib.GetProtoValue<double>(module, "waste_rate");
           greenhouse.harvest_size = Lib.GetProtoValue<double>(module, "harvest_size");
           greenhouse.growth_rate = Lib.GetProtoValue<double>(module, "growth_rate");
           greenhouse.door_opened = Lib.GetProtoValue<bool>(module, "door_opened");
           greenhouse.growth = Lib.GetProtoValue<double>(module, "growth");
           greenhouse.lamps = Lib.GetProtoValue<float>(module, "lamps");
           greenhouse.lighting = Lib.GetProtoValue<double>(module, "lighting");
           ret.Add(greenhouse);
         }
       }
     }
     return ret;
   }
 }
Ejemplo n.º 2
0
        private void EvaluateStatus()
        {
            UnityEngine.Profiling.Profiler.BeginSample("Kerbalism.VesselData.EvaluateStatus");
            // determine if there is enough EC for a powered state
            powered = Lib.IsPowered(Vessel);

            // calculate crew info for the vessel
            crewCount    = Lib.CrewCount(Vessel);
            crewCapacity = Lib.CrewCapacity(Vessel);

            // malfunction stuff
            malfunction = Reliability.HasMalfunction(Vessel);
            critical    = Reliability.HasCriticalFailure(Vessel);

            // communications info
            connection = ConnectionInfo.Update(Vessel, powered, EnvBlackout);

            // habitat data
            habitatInfo.Update(Vessel);
            volume   = Habitat.Tot_volume(Vessel);
            surface  = Habitat.Tot_surface(Vessel);
            pressure = Math.Min(Habitat.Pressure(Vessel), habitatInfo.MaxPressure);

            evas          = (uint)(Math.Max(0, ResourceCache.GetResource(Vessel, "Nitrogen").Amount - 330) / Settings.LifeSupportAtmoLoss);
            poisoning     = Habitat.Poisoning(Vessel);
            shielding     = Habitat.Shielding(Vessel);
            livingSpace   = Habitat.Living_space(Vessel);
            volumePerCrew = Habitat.Volume_per_crew(Vessel);
            comforts      = new Comforts(Vessel, EnvLanded, crewCount > 1, connection.linked && connection.rate > double.Epsilon);

            // data about greenhouses
            greenhouses = Greenhouse.Greenhouses(Vessel);

            Drive.GetCapacity(this, out drivesFreeSpace, out drivesCapacity);

            // solar panels data
            if (Vessel.loaded)
            {
                solarPanelsAverageExposure = SolarPanelFixer.GetSolarPanelsAverageExposure(solarPanelsExposure);
                solarPanelsExposure.Clear();
            }
            UnityEngine.Profiling.Profiler.EndSample();
        }
Ejemplo n.º 3
0
 // return read-only list of greenhouses in a vessel
 public static List<Greenhouse> GetGreenhouses(Vessel v, string resource_name="")
 {
   if (v.loaded)
   {
     var ret = v.FindPartModulesImplementing<Greenhouse>();
     if (resource_name.Length > 0) ret = ret.FindAll(k => k.resource_name == resource_name);
     return ret == null ? new List<Greenhouse>() : ret;
   }
   else
   {
     List<Greenhouse> ret = new List<Greenhouse>();
     foreach(ProtoPartSnapshot part in v.protoVessel.protoPartSnapshots)
     {
       foreach(ProtoPartModuleSnapshot module in part.modules)
       {
         if (module.moduleName == "Greenhouse")
         {
           Greenhouse greenhouse = new Greenhouse();
           greenhouse.resource_name = Lib.GetProtoValue(module, "resource_name", "Food");  //< support versions before 0.9.9.5
           greenhouse.waste_name = Lib.GetProtoValue(module, "waste_name", "Crap");  //< support versions before 0.9.9.5
           greenhouse.input_name = Lib.GetProtoValue(module, "input_name", "");  //< from version 0.9.9.8
           greenhouse.ec_rate = Lib.GetProtoValue<double>(module, "ec_rate");
           greenhouse.waste_rate = Lib.GetProtoValue<double>(module, "waste_rate");
           greenhouse.input_rate = Lib.GetProtoValue<double>(module, "input_rate", 0.0);
           greenhouse.harvest_size = Lib.GetProtoValue<double>(module, "harvest_size");
           greenhouse.growth_rate = Lib.GetProtoValue<double>(module, "growth_rate");
           greenhouse.waste_bonus = Lib.GetProtoValue(module, "waste_bonus", 0.2); //< support versions before 0.9.9.5
           greenhouse.soil_bonus = Lib.GetProtoValue(module, "soil_bonus", 0.5);  //< support versions before 0.9.9.5
           greenhouse.door_opened = Lib.GetProtoValue<bool>(module, "door_opened");
           greenhouse.growth = Lib.GetProtoValue<double>(module, "growth");
           greenhouse.lamps = Lib.GetProtoValue<float>(module, "lamps");
           greenhouse.lighting = Lib.GetProtoValue<double>(module, "lighting");
           greenhouse.growing = Lib.GetProtoValue<double>(module, "growing");
           if (resource_name.Length == 0 || greenhouse.resource_name == resource_name) ret.Add(greenhouse);
         }
       }
     }
     return ret;
   }
 }
Ejemplo n.º 4
0
        public static void BackgroundUpdate(Vessel v, ProtoPartModuleSnapshot m, Greenhouse g,
                                            Vessel_info vi, Vessel_resources resources, double elapsed_s)
        {
            // get protomodule data
            bool   active = Lib.Proto.GetBool(m, "active");
            double growth = Lib.Proto.GetDouble(m, "growth");

            // if enabled and not ready for harvest
            if (active && growth < 0.99)
            {
                // get resource handler
                Resource_info ec = resources.Info(v, "ElectricCharge");

                // calculate natural and artificial lighting
                double natural    = vi.solar_flux;
                double artificial = Math.Max(g.light_tolerance - natural, 0.0);

                // consume EC for the lamps, scaled by artificial light intensity
                if (artificial > double.Epsilon)
                {
                    ec.Consume(g.ec_rate * (artificial / g.light_tolerance) * elapsed_s, "greenhouse");
                }

                // reset artificial lighting if there is no ec left
                // note: comparing against amount in previous simulation step
                if (ec.amount <= double.Epsilon)
                {
                    artificial = 0.0;
                }

                // execute recipe
                Resource_recipe recipe = new Resource_recipe(g.part, "greenhouse");
                foreach (ModuleResource input in g.resHandler.inputResources)                 //recipe.Input(input.name, input.rate * elapsed_s);
                {
                    // WasteAtmosphere is primary combined input
                    if (g.WACO2 && input.name == "WasteAtmosphere")
                    {
                        recipe.Input(input.name, vi.breathable ? 0.0 : input.rate * elapsed_s, "CarbonDioxide");
                    }
                    // CarbonDioxide is secondary combined input
                    else if (g.WACO2 && input.name == "CarbonDioxide")
                    {
                        recipe.Input(input.name, vi.breathable ? 0.0 : input.rate * elapsed_s, "");
                    }
                    // if atmosphere is breathable disable WasteAtmosphere / CO2
                    else if (!g.WACO2 && (input.name == "CarbonDioxide" || input.name == "WasteAtmosphere"))
                    {
                        recipe.Input(input.name, vi.breathable ? 0.0 : input.rate, "");
                    }
                    else
                    {
                        recipe.Input(input.name, input.rate * elapsed_s);
                    }
                }
                foreach (ModuleResource output in g.resHandler.outputResources)
                {
                    // if atmosphere is breathable disable Oxygen
                    if (output.name == "Oxygen")
                    {
                        recipe.Output(output.name, vi.breathable ? 0.0 : output.rate * elapsed_s, true);
                    }
                    else
                    {
                        recipe.Output(output.name, output.rate * elapsed_s, true);
                    }
                }
                resources.Transform(recipe);

                // determine environment conditions
                bool lighting  = natural + artificial >= g.light_tolerance;
                bool pressure  = g.pressure_tolerance <= double.Epsilon || vi.pressure >= g.pressure_tolerance;
                bool radiation = g.radiation_tolerance <= double.Epsilon || vi.radiation * (1.0 - vi.shielding) < g.radiation_tolerance;

                // determine inputs conditions
                // note: comparing against amounts in previous simulation step
                bool   inputs      = true;
                string missing_res = string.Empty;
                bool   dis_WACO2   = false;
                foreach (ModuleResource input in g.resHandler.inputResources)
                {
                    // combine WasteAtmosphere and CO2 if both exist
                    if (input.name == "WasteAtmosphere" || input.name == "CarbonDioxide")
                    {
                        if (dis_WACO2 || vi.breathable)
                        {
                            continue;                                                        // skip if already checked or atmosphere is breathable
                        }
                        if (g.WACO2)
                        {
                            if (resources.Info(v, "WasteAtmosphere").amount <= double.Epsilon && resources.Info(v, "CarbonDioxide").amount <= double.Epsilon)
                            {
                                inputs      = false;
                                missing_res = "CarbonDioxide";
                                break;
                            }
                            dis_WACO2 = true;
                            continue;
                        }
                    }
                    if (resources.Info(v, input.name).amount <= double.Epsilon)
                    {
                        inputs      = false;
                        missing_res = input.name;
                        break;
                    }
                }

                // if growing
                if (lighting && pressure && radiation && inputs)
                {
                    // increase growth
                    growth += g.crop_rate * elapsed_s;
                    growth  = Math.Min(growth, 1.0);

                    // notify the user when crop can be harvested
                    if (growth >= 0.99)
                    {
                        Message.Post(Lib.BuildString("On <b>", v.vesselName, "</b> the crop is ready to be harvested"));
                        growth = 1.0;
                    }
                }

                // update time-to-harvest
                double tta = (1.0 - growth) / g.crop_rate;

                // update issues
                string issue =
                    !inputs?Lib.BuildString("missing ", missing_res)
                        : !lighting ? "insufficient lighting"
                                : !pressure ? "insufficient pressure"
                                : !radiation ? "excessive radiation"
                                : string.Empty;

                // update protomodule data
                Lib.Proto.Set(m, "natural", natural);
                Lib.Proto.Set(m, "artificial", artificial);
                Lib.Proto.Set(m, "tta", tta);
                Lib.Proto.Set(m, "issue", issue);
                Lib.Proto.Set(m, "growth", growth);
            }
        }
Ejemplo n.º 5
0
  // draw a vessel in the monitor
  // - return: 1 if vessel wasn't skipped
  uint render_vessel(Vessel v)
  {
    // avoid case when DB isn't ready for whatever reason
    if (!DB.Ready()) return 0;

    // skip invalid vessels
    if (!Lib.IsVessel(v)) return 0;

    // skip resque missions
    if (Lib.IsResqueMission(v)) return 0;

    // skip dead eva kerbals
    if (EVA.IsDead(v)) return 0;

    // get vessel info from cache
    vessel_info vi = Cache.VesselInfo(v);

    // get vessel data from the db
    vessel_data vd = DB.VesselData(v.id);

    // skip filtered vessels
    if (filtered() && vd.group != filter) return 0;

    // get vessel crew
    List<ProtoCrewMember> crew = v.loaded ? v.GetVesselCrew() : v.protoVessel.GetVesselCrew();

    // get vessel name
    string vessel_name = v.isEVA ? crew[0].name : v.vesselName;

    // get body name
    string body_name = v.mainBody.name.ToUpper();

    // get list of scrubbers
    List<Scrubber> scrubbers = Scrubber.GetScrubbers(v);

    // get list of greenhouses
    List<Greenhouse> greenhouses = Greenhouse.GetGreenhouses(v);

    // store problems icons & tooltips
    List<Texture> problem_icons = new List<Texture>();
    List<string> problem_tooltips = new List<string>();

    // detect problems
    problem_sunlight(vi, ref problem_icons, ref problem_tooltips);
    problem_storm(v, ref problem_icons, ref problem_tooltips);
    if (crew.Count > 0)
    {
      problem_kerbals(crew, ref problem_icons, ref problem_tooltips);
      problem_radiation(vi, ref problem_icons, ref problem_tooltips);
      problem_scrubbers(v, scrubbers, ref problem_icons, ref problem_tooltips);
    }
    problem_greenhouses(v, greenhouses, ref problem_icons, ref problem_tooltips);

    // choose problem icon
    const UInt64 problem_icon_time = 3;
    Texture problem_icon = icon_empty;
    if (problem_icons.Count > 0)
    {
      UInt64 problem_index = (Convert.ToUInt64(Time.realtimeSinceStartup) / problem_icon_time) % (UInt64)(problem_icons.Count);
      problem_icon = problem_icons[(int)problem_index];
    }

    // generate problem tooltips
    string problem_tooltip = String.Join("\n", problem_tooltips.ToArray());

    // render vessel name & icons
    GUILayout.BeginHorizontal(row_style);
    GUILayout.Label(new GUIContent("<b>" + Lib.Epsilon(vessel_name, 20) + "</b>", vessel_name.Length > 20 ? vessel_name : ""), name_style);
    GUILayout.Label(new GUIContent(Lib.Epsilon(body_name, 8), body_name.Length > 8 ? body_name : ""), body_style);
    GUILayout.Label(new GUIContent(problem_icon, problem_tooltip), icon_style);
    GUILayout.Label(indicator_ec(v), icon_style);
    GUILayout.Label(indicator_supplies(v, scrubbers, greenhouses), icon_style);
    GUILayout.Label(indicator_reliability(v), icon_style);
    GUILayout.Label(indicator_signal(v), icon_style);
    GUILayout.EndHorizontal();

    // remember last vessel clicked
    if (Lib.IsClicked()) last_clicked_id = v.id;

    // render vessel config
    if (configured_id == v.id) render_config(v);

    // spacing between vessels
    GUILayout.Space(10.0f);

    // signal that the vessel wasn't skipped for whatever reason
    return 1;
  }
Ejemplo n.º 6
0
        public Vessel_info(Vessel v, UInt64 vessel_id, UInt64 inc)
        {
            // NOTE: anything used here can't in turn use cache, unless you know what you are doing

            // NOTE: you can't cache vessel position
            // at any point in time all vessel/body positions are relative to a different frame of reference
            // so comparing the current position of a vessel, with the cached one of another make no sense

            // associate with an unique incremental id
            this.inc = inc;

            // determine if this is a valid vessel
            is_vessel = Lib.IsVessel(v);
            if (!is_vessel)
            {
                return;
            }

            // determine if this is a rescue mission vessel
            is_rescue = Misc.IsRescueMission(v);
            if (is_rescue)
            {
                return;
            }

            // dead EVA are not valid vessels
            if (EVA.IsDead(v))
            {
                return;
            }

            // shortcut for common tests
            is_valid = true;

            // generate id once
            id = vessel_id;

            // calculate crew info for the vessel
            crew_count    = Lib.CrewCount(v);
            crew_capacity = Lib.CrewCapacity(v);

            // get vessel position
            Vector3d position = Lib.VesselPosition(v);

            // this should never happen again
            if (Vector3d.Distance(position, v.mainBody.position) < 1.0)
            {
                throw new Exception("Shit hit the fan for vessel " + v.vesselName);
            }

            // determine if there is enough EC for a powered state
            powered = ResourceCache.Info(v, "ElectricCharge").amount > double.Epsilon;

            // determine if in sunlight, calculate sun direction and distance
            sunlight = Sim.RaytraceBody(v, position, FlightGlobals.Bodies[0], out sun_dir, out sun_dist) ? 1.0 : 0.0;

            // environment stuff
            atmo_factor        = Sim.AtmosphereFactor(v.mainBody, position, sun_dir);
            gamma_transparency = Sim.GammaTransparency(v.mainBody, v.altitude);
            underwater         = Sim.Underwater(v);
            breathable         = Sim.Breathable(v, underwater);
            landed             = Lib.Landed(v);
            zerog = !landed && (!v.mainBody.atmosphere || v.mainBody.atmosphereDepth < v.altitude);

            if (v.mainBody.flightGlobalsIndex != 0 && TimeWarp.CurrentRate > 1000.0f)
            {
                highspeedWarp(v);
            }

            // temperature at vessel position
            temperature = Sim.Temperature(v, position, sunlight, atmo_factor, out solar_flux, out albedo_flux, out body_flux, out total_flux);
            temp_diff   = Sim.TempDiff(temperature, v.mainBody, landed);

            // radiation
            radiation = Radiation.Compute(v, position, gamma_transparency, sunlight, out blackout, out magnetosphere, out inner_belt, out outer_belt, out interstellar);

            // extended atmosphere
            thermosphere = Sim.InsideThermosphere(v);
            exosphere    = Sim.InsideExosphere(v);

            // malfunction stuff
            malfunction = Reliability.HasMalfunction(v);
            critical    = Reliability.HasCriticalFailure(v);

            // communications info
            connection   = new ConnectionInfo(v, powered, blackout);
            transmitting = Science.Transmitting(v, connection.linked && connection.rate > double.Epsilon);

            // habitat data
            volume          = Habitat.Tot_volume(v);
            surface         = Habitat.Tot_surface(v);
            pressure        = Habitat.Pressure(v);
            evas            = (uint)(Math.Max(0, ResourceCache.Info(v, "Nitrogen").amount - 330) / PreferencesLifeSupport.Instance.evaAtmoLoss);
            poisoning       = Habitat.Poisoning(v);
            humidity        = Habitat.Humidity(v);
            shielding       = Habitat.Shielding(v);
            living_space    = Habitat.Living_space(v);
            volume_per_crew = Habitat.Volume_per_crew(v);
            comforts        = new Comforts(v, landed, crew_count > 1, connection.linked && connection.rate > double.Epsilon);

            // data about greenhouses
            greenhouses = Greenhouse.Greenhouses(v);

            // other stuff
            gravioli = Sim.Graviolis(v);
        }
Ejemplo n.º 7
0
  // called at every simulation step
  public void FixedUpdate()
  {
    // do nothing if paused
    if (Lib.IsPaused()) return;

    // do nothing if DB isn't ready
    if (!DB.Ready()) return;

    // for each vessel
    foreach(Vessel vessel in FlightGlobals.Vessels)
    {
      // skip invalid vessels
      if (!Lib.IsVessel(vessel)) continue;

      // skip loaded vessels
      if (vessel.loaded) continue;

      // get vessel info from the cache
      vessel_info info = Cache.VesselInfo(vessel);

      // calculate atmospheric factor (proportion of flux not blocked by atmosphere)
      double atmo_factor = Sim.AtmosphereFactor(vessel.mainBody, info.position, info.sun_dir);

      // for each part
      foreach(ProtoPartSnapshot part in vessel.protoVessel.protoPartSnapshots)
      {
        // get part prefab (required for module properties)
        Part part_prefab = PartLoader.getPartInfoByName(part.partName).partPrefab;

        // store index of ModuleResourceConverter to process
        // rationale: a part can contain multiple resource converters
        int converter_index = 0;

        // for each module
        foreach(ProtoPartModuleSnapshot module in part.modules)
        {
          // command module
          if (module.moduleName == "ModuleCommand")
          {
            // get module from prefab
            ModuleCommand command = part_prefab.Modules.GetModules<ModuleCommand>()[0];

            // do not consume if this is a MCM with no crew
            // rationale: for consistency, the game doesn't consume resources for MCM without crew in loaded vessels
            //            this make some sense: you left a vessel with some battery and nobody on board, you expect it to not consume EC
            if (command.minimumCrew == 0 || part.protoModuleCrew.Count > 0)
            {
              // for each input resource
              foreach(ModuleResource ir in command.inputResources)
              {
                // consume the resource
                Lib.RequestResource(vessel, ir.name, ir.rate * TimeWarp.fixedDeltaTime);
              }
            }
          }
          // solar panel
          else if (module.moduleName == "ModuleDeployableSolarPanel")
          {
            // determine if extended
            bool extended = module.moduleValues.GetValue("stateString") == ModuleDeployableSolarPanel.panelStates.EXTENDED.ToString();

            // if in sunlight and extended
            if (info.sunlight && extended)
            {
              // get module from prefab
              ModuleDeployableSolarPanel panel = part_prefab.Modules.GetModules<ModuleDeployableSolarPanel>()[0];

              // produce electric charge
              Lib.RequestResource(vessel, "ElectricCharge", -PanelOutput(vessel, part, panel, info.sun_dir, info.sun_dist, atmo_factor) * TimeWarp.fixedDeltaTime * Malfunction.Penalty(part));
            }
          }
          // generator
          // note: assume generators require all input
          else if (module.moduleName == "ModuleGenerator")
          {
            // determine if active
            bool activated = Convert.ToBoolean(module.moduleValues.GetValue("generatorIsActive"));

            // if active
            if (activated)
            {
              // get module from prefab
              ModuleGenerator generator = part_prefab.Modules.GetModules<ModuleGenerator>()[0];

              // determine if vessel is full of all output resources
              bool full = true;
              foreach(var or in generator.outputList)
              {
                double amount = Lib.GetResourceAmount(vessel, or.name);
                double capacity = Lib.GetResourceCapacity(vessel, or.name);
                double perc = capacity > 0.0 ? amount / capacity : 0.0;
                full &= (perc >= 1.0 - double.Epsilon);
              }

              // if not full
              if (!full)
              {
                // calculate worst required resource percentual
                double worst_input = 1.0;
                foreach(var ir in generator.inputList)
                {
                  double required = ir.rate * TimeWarp.fixedDeltaTime;
                  double amount = Lib.GetResourceAmount(vessel, ir.name);
                  worst_input = Math.Min(worst_input, amount / required);
                }

                // for each input resource
                foreach(var ir in generator.inputList)
                {
                  // consume the resource
                  Lib.RequestResource(vessel, ir.name, ir.rate * worst_input * TimeWarp.fixedDeltaTime);
                }

                // for each output resource
                foreach(var or in generator.outputList)
                {
                  // produce the resource
                  Lib.RequestResource(vessel, or.name, -or.rate * worst_input * TimeWarp.fixedDeltaTime * Malfunction.Penalty(part));
                }
              }
            }
          }
          // converter
          // note: support multiple resource converters
          // note: ignore stock temperature mechanic of converters
          // note: ignore autoshutdown
          // note: ignore crew experience bonus (seem that stock ignore it too)
          // note: 'undo' stock behaviour by forcing lastUpdateTime to now (to minimize overlapping calculations from this and stock post-facto simulation)
          else if (module.moduleName == "ModuleResourceConverter")
          {
            // determine if active
            bool activated = Convert.ToBoolean(module.moduleValues.GetValue("IsActivated"));

            // if active
            if (activated)
            {
              // get module from prefab
              ModuleResourceConverter converter = part_prefab.Modules.GetModules<ModuleResourceConverter>()[converter_index++];

              // determine if vessel is full of all output resources
              bool full = true;
              foreach(var or in converter.outputList)
              {
                double amount = Lib.GetResourceAmount(vessel, or.ResourceName);
                double capacity = Lib.GetResourceCapacity(vessel, or.ResourceName);
                double perc = capacity > 0.0 ? amount / capacity : 0.0;
                full &= (perc >= converter.FillAmount - double.Epsilon);
              }

              // if not full
              if (!full)
              {
                // calculate worst required resource percentual
                double worst_input = 1.0;
                foreach(var ir in converter.inputList)
                {
                  double required = ir.Ratio * TimeWarp.fixedDeltaTime;
                  double amount = Lib.GetResourceAmount(vessel, ir.ResourceName);
                  worst_input = Math.Min(worst_input, amount / required);
                }

                // for each input resource
                foreach(var ir in converter.inputList)
                {
                  // consume the resource
                  Lib.RequestResource(vessel, ir.ResourceName, ir.Ratio * worst_input * TimeWarp.fixedDeltaTime);
                }

                // for each output resource
                foreach(var or in converter.outputList)
                {
                  // produce the resource
                  Lib.RequestResource(vessel, or.ResourceName, -or.Ratio * worst_input * TimeWarp.fixedDeltaTime * Malfunction.Penalty(part));
                }
              }

              // undo stock behaviour by forcing last_update_time to now
              module.moduleValues.SetValue("lastUpdateTime", Planetarium.GetUniversalTime().ToString());
            }
          }
          // drill
          // note: ignore stock temperature mechanic of harvesters
          // note: ignore autoshutdown
          // note: ignore depletion (stock seem to do the same)
          // note: 'undo' stock behaviour by forcing lastUpdateTime to now (to minimize overlapping calculations from this and stock post-facto simulation)
          else if (module.moduleName == "ModuleResourceHarvester")
          {
            // determine if active
            bool activated = Convert.ToBoolean(module.moduleValues.GetValue("IsActivated"));

            // if active
            if (activated)
            {
              // get module from prefab
              ModuleResourceHarvester harvester = part_prefab.Modules.GetModules<ModuleResourceHarvester>()[0];

              // deduce crew bonus
              double experience_bonus = 0.0;
              if (harvester.UseSpecialistBonus)
              {
                foreach(ProtoCrewMember c in vessel.protoVessel.GetVesselCrew())
                {
                  experience_bonus = Math.Max(experience_bonus, (c.trait == harvester.Specialty) ? (double)c.experienceLevel : 0.0);
                }
              }
              double crew_bonus = harvester.SpecialistBonusBase + (experience_bonus + 1.0) * harvester.SpecialistEfficiencyFactor;

              // detect amount of ore in the ground
              AbundanceRequest request = new AbundanceRequest
              {
                Altitude = vessel.altitude,
                BodyId = vessel.mainBody.flightGlobalsIndex,
                CheckForLock = false,
                Latitude = vessel.latitude,
                Longitude = vessel.longitude,
                ResourceType = (HarvestTypes)harvester.HarvesterType,
                ResourceName = harvester.ResourceName
              };
              double abundance = ResourceMap.Instance.GetAbundance(request);

              // if there is actually something (should be if active when unloaded)
              if (abundance > harvester.HarvestThreshold)
              {
                // calculate worst required resource percentual
                double worst_input = 1.0;
                foreach(var ir in harvester.inputList)
                {
                  double required = ir.Ratio * TimeWarp.fixedDeltaTime;
                  double amount = Lib.GetResourceAmount(vessel, ir.ResourceName);
                  worst_input = Math.Min(worst_input, amount / required);
                }

                // for each input resource
                foreach(var ir in harvester.inputList)
                {
                  // consume the resource
                  Lib.RequestResource(vessel, ir.ResourceName, ir.Ratio * worst_input * TimeWarp.fixedDeltaTime);
                }

                // determine resource produced
                double res = abundance * harvester.Efficiency * crew_bonus * worst_input * Malfunction.Penalty(part);

                // accumulate ore
                Lib.RequestResource(vessel, harvester.ResourceName, -res * TimeWarp.fixedDeltaTime);
              }

              // undo stock behaviour by forcing last_update_time to now
              module.moduleValues.SetValue("lastUpdateTime", Planetarium.GetUniversalTime().ToString());
            }
          }
          // asteroid drill
          // note: untested
          // note: ignore stock temperature mechanic of asteroid drills
          // note: ignore autoshutdown
          // note: 'undo' stock behaviour by forcing lastUpdateTime to now (to minimize overlapping calculations from this and stock post-facto simulation)
          else if (module.moduleName == "ModuleAsteroidDrill")
          {
            // determine if active
            bool activated = Convert.ToBoolean(module.moduleValues.GetValue("IsActivated"));

            // if active
            if (activated)
            {
              // get module from prefab
              ModuleAsteroidDrill asteroid_drill = part_prefab.Modules.GetModules<ModuleAsteroidDrill>()[0];

              // deduce crew bonus
              double experience_bonus = 0.0;
              if (asteroid_drill.UseSpecialistBonus)
              {
                foreach(ProtoCrewMember c in vessel.protoVessel.GetVesselCrew())
                {
                  experience_bonus = Math.Max(experience_bonus, (c.trait == asteroid_drill.Specialty) ? (double)c.experienceLevel : 0.0);
                }
              }
              double crew_bonus = asteroid_drill.SpecialistBonusBase + (experience_bonus + 1.0) * asteroid_drill.SpecialistEfficiencyFactor;

              // get asteroid data
              ProtoPartModuleSnapshot asteroid_info = null;
              ProtoPartModuleSnapshot asteroid_resource = null;
              foreach(ProtoPartSnapshot p in vessel.protoVessel.protoPartSnapshots)
              {
                if (asteroid_info == null) asteroid_info = p.modules.Find(k => k.moduleName == "ModuleAsteroidInfo");
                if (asteroid_resource == null) asteroid_resource = p.modules.Find(k => k.moduleName == "ModuleAsteroidResource");
              }

              // if there is actually an asteroid attached to this active asteroid drill (it should)
              if (asteroid_info != null && asteroid_resource != null)
              {
                // get some data
                double mass_threshold = Convert.ToDouble(asteroid_info.moduleValues.GetValue("massThresholdVal"));
                double mass = Convert.ToDouble(asteroid_info.moduleValues.GetValue("currentMassVal"));
                double abundance = Convert.ToDouble(asteroid_resource.moduleValues.GetValue("abundance"));
                string res_name = asteroid_resource.moduleValues.GetValue("resourceName");
                double res_density = PartResourceLibrary.Instance.GetDefinition(res_name).density;

                // if asteroid isn't depleted
                if (mass > mass_threshold && abundance > double.Epsilon)
                {
                  // consume EC
                  double ec_required = asteroid_drill.PowerConsumption * TimeWarp.fixedDeltaTime;
                  double ec_consumed = Lib.RequestResource(vessel, "ElectricCharge", ec_required);
                  double ec_ratio = ec_consumed / ec_required;

                  // determine resource extracted
                  double res_amount = abundance * asteroid_drill.Efficiency * crew_bonus * ec_ratio * TimeWarp.fixedDeltaTime;

                  // produce mined resource
                  Lib.RequestResource(vessel, res_name, -res_amount);

                  // consume asteroid mass
                  asteroid_info.moduleValues.SetValue("currentMassVal", (mass - res_density * res_amount).ToString());
                }
              }

              // undo stock behaviour by forcing last_update_time to now
              module.moduleValues.SetValue("lastUpdateTime", Planetarium.GetUniversalTime().ToString());
            }
          }
          // SCANSAT support (new version)
          // TODO: enable better SCANsat support
          /*else if (module.moduleName == "SCANsat" || module.moduleName == "ModuleSCANresourceScanner")
          {
            // get ec consumption rate
            PartModule scansat = part_prefab.Modules[module.moduleName];
            double power = Lib.ReflectionValue<float>(scansat, "power");
            double ec_required = power * TimeWarp.fixedDeltaTime;

            // if it was scanning
            if (SCANsat.wasScanning(module))
            {
              // if there is enough ec
              double ec_amount = Lib.GetResourceAmount(vessel, "ElectricCharge");
              double ec_capacity = Lib.GetResourceCapacity(vessel, "ElectricCharge");
              if (ec_capacity > double.Epsilon && ec_amount / ec_capacity > 0.15) //< re-enable at 15% EC
              {
                // re-enable the scanner
                SCANsat.resumeScanner(vessel, module, part_prefab);

                // give the user some feedback
                if (DB.VesselData(vessel.id).cfg_ec == 1)
                  Message.Post(Severity.relax, "SCANsat> sensor on <b>" + vessel.vesselName + "</b> resumed operations", "we got enough ElectricCharge");
              }
            }

            // if it is scanning
            if (SCANsat.isScanning(module))
            {
              // consume ec
              double ec_consumed = Lib.RequestResource(vessel, "ElectricCharge", ec_required);

              // if there isn't enough ec
              if (ec_consumed < ec_required * 0.99 && ec_required > double.Epsilon)
              {
                // unregister scanner, and remember it
                SCANsat.stopScanner(vessel, module, part_prefab);

                // give the user some feedback
                if (DB.VesselData(vessel.id).cfg_ec == 1)
                  Message.Post(Severity.warning, "SCANsat sensor was disabled on <b>" + vessel.vesselName + "</b>", "for lack of ElectricCharge");
              }
            }
          }*/
          // SCANSAT support (old version)
          // note: this one doesn't support re-activation, is a bit slower and less clean
          //       waiting for DMagic to fix a little bug
          else if (module.moduleName == "SCANsat" || module.moduleName == "ModuleSCANresourceScanner")
          {
            // determine if scanning
            bool scanning = Convert.ToBoolean(module.moduleValues.GetValue("scanning"));

            // consume ec
            if (scanning)
            {
              // get ec consumption
              PartModule scansat = part_prefab.Modules[module.moduleName];
              double power = Lib.ReflectionValue<float>(scansat, "power");

              // consume ec
              double ec_required = power * TimeWarp.fixedDeltaTime;
              double ec_consumed = Lib.RequestResource(vessel, "ElectricCharge", ec_required);

              // if there isn't enough ec
              if (ec_consumed < ec_required * 0.99 && ec_required > double.Epsilon)
              {
                // unregister scanner using reflection
                foreach(var a in AssemblyLoader.loadedAssemblies)
                {
                  if (a.name == "SCANsat")
                  {
                    Type controller_type = a.assembly.GetType("SCANsat.SCANcontroller");
                    System.Object controller = controller_type.GetProperty("controller", BindingFlags.Public | BindingFlags.Static).GetValue(null, null);
                    controller_type.InvokeMember("removeVessel", BindingFlags.InvokeMethod | BindingFlags.NonPublic | BindingFlags.Instance, null, controller, new System.Object[]{vessel});
                  }
                }

                // disable scanning
                module.moduleValues.SetValue("scanning", false.ToString());

                // give the user some feedback
                if (DB.VesselData(vessel.id).cfg_ec == 1)
                  Message.Post(Severity.warning, "SCANsat sensor was disabled on <b>" + vessel.vesselName + "</b>", "for lack of ElectricCharge");
              }
            }
          }
          // NearFutureSolar support
          // note: we assume deployed, this is a current limitation
          else if (module.moduleName == "ModuleCurvedSolarPanel")
          {
            // [unused] determine if extended
            //string state = module.moduleValues.GetValue("SavedState");
            //bool extended = state == ModuleDeployableSolarPanel.panelStates.EXTENDED.ToString();

            // if in sunlight
            if (info.sunlight)
            {
              // produce electric charge
              double output = CurvedPanelOutput(vessel, part, part_prefab, info.sun_dir, info.sun_dist, atmo_factor) * Malfunction.Penalty(part);
              Lib.RequestResource(vessel, "ElectricCharge", -output * TimeWarp.fixedDeltaTime);
            }
          }
          // KERBALISM modules
          else if (module.moduleName == "Scrubber") { Scrubber.BackgroundUpdate(vessel, part.flightID); }
          else if (module.moduleName == "Greenhouse") { Greenhouse.BackgroundUpdate(vessel, part.flightID); }
          else if (module.moduleName == "Malfunction") { Malfunction.BackgroundUpdate(vessel, part.flightID); }
        }
      }
    }
  }
Ejemplo n.º 8
0
        public static void Update(Vessel v, Vessel_info vi, VesselData vd, Vessel_resources resources, double elapsed_s)
        {
            if (!Lib.IsVessel(v))
            {
                return;
            }

            // get most used resource handlers
            Resource_info ec = resources.Info(v, "ElectricCharge");

            // This is basically handled in cache. However, when accelerating time warp while
            // the vessel is in shadow, the cache logic doesn't kick in soon enough. So we double-check here
            if (TimeWarp.CurrentRate > 1000.0f || elapsed_s > 150)              // we're time warping fast...
            {
                vi.highspeedWarp(v);
            }

            foreach (var e in Background_PMs(v))
            {
                switch (e.type)
                {
                case Module_type.Reliability: Reliability.BackgroundUpdate(v, e.p, e.m, e.module_prefab as Reliability); break;

                case Module_type.Experiment: Experiment.BackgroundUpdate(v, e.m, e.module_prefab as Experiment, ec, resources, elapsed_s); break;

                case Module_type.Greenhouse: Greenhouse.BackgroundUpdate(v, e.m, e.module_prefab as Greenhouse, vi, resources, elapsed_s); break;

                case Module_type.GravityRing: GravityRing.BackgroundUpdate(v, e.p, e.m, e.module_prefab as GravityRing, ec, elapsed_s); break;

                case Module_type.Emitter: Emitter.BackgroundUpdate(v, e.p, e.m, e.module_prefab as Emitter, ec, elapsed_s); break;

                case Module_type.Harvester: Harvester.BackgroundUpdate(v, e.m, e.module_prefab as Harvester, elapsed_s); break;                         // Kerbalism ground and air harvester module

                case Module_type.Laboratory: Laboratory.BackgroundUpdate(v, e.p, e.m, e.module_prefab as Laboratory, ec, elapsed_s); break;

                case Module_type.Command: ProcessCommand(v, e.p, e.m, e.module_prefab as ModuleCommand, resources, elapsed_s); break;

                case Module_type.Panel: ProcessPanel(v, e.p, e.m, e.module_prefab as ModuleDeployableSolarPanel, vi, ec, elapsed_s); break;

                case Module_type.Generator: ProcessGenerator(v, e.p, e.m, e.module_prefab as ModuleGenerator, resources, elapsed_s); break;

                case Module_type.Converter: ProcessConverter(v, e.p, e.m, e.module_prefab as ModuleResourceConverter, resources, elapsed_s); break;

                case Module_type.Drill: ProcessDrill(v, e.p, e.m, e.module_prefab as ModuleResourceHarvester, resources, elapsed_s); break;                         // Stock ground harvester module

                case Module_type.AsteroidDrill: ProcessAsteroidDrill(v, e.p, e.m, e.module_prefab as ModuleAsteroidDrill, resources, elapsed_s); break;             // Stock asteroid harvester module

                case Module_type.StockLab: ProcessStockLab(v, e.p, e.m, e.module_prefab as ModuleScienceConverter, ec, elapsed_s); break;

                case Module_type.Light: ProcessLight(v, e.p, e.m, e.module_prefab as ModuleLight, ec, elapsed_s); break;

                case Module_type.Scanner: KerbalismScansat.BackgroundUpdate(v, e.p, e.m, e.module_prefab as KerbalismScansat, e.part_prefab, vd, ec, elapsed_s); break;

                case Module_type.CurvedPanel: ProcessCurvedPanel(v, e.p, e.m, e.module_prefab, e.part_prefab, vi, ec, elapsed_s); break;

                case Module_type.FissionGenerator: ProcessFissionGenerator(v, e.p, e.m, e.module_prefab, ec, elapsed_s); break;

                case Module_type.RadioisotopeGenerator: ProcessRadioisotopeGenerator(v, e.p, e.m, e.module_prefab, ec, elapsed_s); break;

                case Module_type.CryoTank: ProcessCryoTank(v, e.p, e.m, e.module_prefab, resources, ec, elapsed_s); break;

                case Module_type.FNGenerator: ProcessFNGenerator(v, e.p, e.m, e.module_prefab, ec, elapsed_s); break;

                case Module_type.NonRechargeBattery: ProcessNonRechargeBattery(v, e.p, e.m, e.module_prefab, ec, elapsed_s); break;

                case Module_type.KerbalismProcess: KerbalismProcess.BackgroundUpdate(v, e.m, e.module_prefab as KerbalismProcess, ec, resources, elapsed_s); break;
                }
            }
        }
Ejemplo n.º 9
0
        public static void Update(Vessel v, VesselData vd, VesselResources resources, double elapsed_s)
        {
            if (!Lib.IsVessel(v))
            {
                return;
            }

            // get most used resource handlers
            ResourceInfo ec = resources.GetResource(v, "ElectricCharge");

            List <ResourceInfo>         allResources       = resources.GetAllResources(v);
            Dictionary <string, double> availableResources = new Dictionary <string, double>();

            foreach (var ri in allResources)
            {
                availableResources[ri.ResourceName] = ri.Amount;
            }
            List <KeyValuePair <string, double> > resourceChangeRequests = new List <KeyValuePair <string, double> >();

            foreach (var e in Background_PMs(v))
            {
                switch (e.type)
                {
                case Module_type.Reliability: Reliability.BackgroundUpdate(v, e.p, e.m, e.module_prefab as Reliability, elapsed_s); break;

                case Module_type.Experiment: (e.module_prefab as Experiment).BackgroundUpdate(v, vd, e.m, ec, resources, elapsed_s); break;                         // experiments use the prefab as a singleton instead of a static method

                case Module_type.Greenhouse: Greenhouse.BackgroundUpdate(v, e.m, e.module_prefab as Greenhouse, vd, resources, elapsed_s); break;

                case Module_type.GravityRing: GravityRing.BackgroundUpdate(v, e.p, e.m, e.module_prefab as GravityRing, ec, elapsed_s); break;

                case Module_type.Harvester: Harvester.BackgroundUpdate(v, e.m, e.module_prefab as Harvester, elapsed_s); break;                         // Kerbalism ground and air harvester module

                case Module_type.Laboratory: Laboratory.BackgroundUpdate(v, e.p, e.m, e.module_prefab as Laboratory, ec, elapsed_s); break;

                case Module_type.Command: ProcessCommand(v, e.p, e.m, e.module_prefab as ModuleCommand, resources, elapsed_s); break;

                case Module_type.Generator: ProcessGenerator(v, e.p, e.m, e.module_prefab as ModuleGenerator, resources, elapsed_s); break;

                case Module_type.Converter: ProcessConverter(v, e.p, e.m, e.module_prefab as ModuleResourceConverter, resources, elapsed_s); break;

                case Module_type.Drill: ProcessDrill(v, e.p, e.m, e.module_prefab as ModuleResourceHarvester, resources, elapsed_s); break;                         // Stock ground harvester module

                // case Module_type.AsteroidDrill: ProcessAsteroidDrill(v, e.p, e.m, e.module_prefab as ModuleAsteroidDrill, resources, elapsed_s); break; // Stock asteroid harvester module
                case Module_type.StockLab: ProcessStockLab(v, e.p, e.m, e.module_prefab as ModuleScienceConverter, ec, elapsed_s); break;

                case Module_type.Light: ProcessLight(v, e.p, e.m, e.module_prefab as ModuleLight, ec, elapsed_s); break;

                case Module_type.Scanner: KerbalismScansat.BackgroundUpdate(v, e.p, e.m, e.module_prefab as KerbalismScansat, e.part_prefab, vd, ec, elapsed_s); break;

                case Module_type.FissionGenerator: ProcessFissionGenerator(v, e.p, e.m, e.module_prefab, ec, elapsed_s); break;

                case Module_type.RadioisotopeGenerator: ProcessRadioisotopeGenerator(v, e.p, e.m, e.module_prefab, ec, elapsed_s); break;

                case Module_type.CryoTank: ProcessCryoTank(v, e.p, e.m, e.module_prefab, resources, ec, elapsed_s); break;

                case Module_type.FNGenerator: ProcessFNGenerator(v, e.p, e.m, e.module_prefab, ec, elapsed_s); break;

                case Module_type.SolarPanelFixer: SolarPanelFixer.BackgroundUpdate(v, e.m, e.module_prefab as SolarPanelFixer, vd, ec, elapsed_s); break;

                case Module_type.KerbalismSentinel: KerbalismSentinel.BackgroundUpdate(v, e.m, e.module_prefab as KerbalismSentinel, vd, ec, elapsed_s); break;

                case Module_type.APIModule: ProcessApiModule(v, e.p, e.m, e.part_prefab, e.module_prefab, resources, availableResources, resourceChangeRequests, elapsed_s); break;
                }
            }
        }
Ejemplo n.º 10
0
  public vessel_info(Vessel v, uint vessel_id, UInt64 inc)
  {
    // NOTE: anything used here can't in turn use cache, unless you know what you are doing

    // associate with an unique incremental id
    this.inc = inc;

    // determine if this is a valid vessel
    is_vessel = Lib.IsVessel(v);
    if (!is_vessel) return;

    // determine if this is a resque mission vessel
    is_resque = Lib.IsResqueMission(v);
    if (is_resque) return;

    // dead EVA are not valid vessels
    if (v.isEVA && EVA.KerbalData(v).eva_dead) return;

    // shortcut for common tests
    is_valid = true;

    // generate id once
    id = vessel_id;

    // calculate crew info for the vessel
    crew_count = Lib.CrewCount(v);
    crew_capacity = Lib.CrewCapacity(v);

    // get vessel position once
    position = Lib.VesselPosition(v);

    // determine if in sunlight, calculate sun direction and distance
    sunlight = Sim.RaytraceBody(v, position, FlightGlobals.Bodies[0], out sun_dir, out sun_dist) ? 1.0 : 0.0;

    // if the orbit length vs simulation step is lower than an acceptable threshold, use discrete sun visibility
    if (v.mainBody.flightGlobalsIndex != 0)
    {
      double orbit_period = Sim.OrbitalPeriod(v);
      if (orbit_period / Kerbalism.elapsed_s < 16.0) sunlight = 1.0 - Sim.ShadowPeriod(v) / orbit_period;
    }

    // calculate environment stuff
    atmo_factor = Sim.AtmosphereFactor(v.mainBody, position, sun_dir);
    gamma_transparency = Sim.GammaTransparency(v.mainBody, v.altitude);
    breathable = Sim.Breathable(v);
    landed = Lib.Landed(v);

    // calculate temperature at vessel position
    temperature = Sim.Temperature(v, position, sunlight, atmo_factor, out solar_flux, out albedo_flux, out body_flux, out total_flux);

    // calculate radiation
    radiation = Radiation.Compute(v, position, gamma_transparency, sunlight, out blackout, out inside_pause, out inside_belt);

    // calculate malfunction stuff
    max_malfunction = Reliability.MaxMalfunction(v);
    avg_quality = Reliability.AverageQuality(v);

    // calculate signal info
    antenna = new antenna_data(v);
    avoid_inf_recursion.Add(v.id);
    link = Signal.Link(v, position, antenna, blackout, avoid_inf_recursion);
    avoid_inf_recursion.Remove(v.id);

    // partial data about modules, used by vessel info/monitor
    scrubbers = Scrubber.PartialData(v);
    recyclers = Recycler.PartialData(v);
    greenhouses = Greenhouse.PartialData(v);

    // woot relativity
    time_dilation = Sim.TimeDilation(v);
  }
Ejemplo n.º 11
0
 public GreenhouseDevice(Greenhouse greenhouse)
 {
   this.greenhouse = greenhouse;
 }
Ejemplo n.º 12
0
  // implement greenhouse mechanics for unloaded vessels
  public static void BackgroundUpdate(Vessel vessel, ProtoPartSnapshot p, ProtoPartModuleSnapshot m, Greenhouse greenhouse, vessel_info info, vessel_resources resources, double elapsed_s)
  {
    // get protomodule data
    bool door_opened = Lib.Proto.GetBool(m, "door_opened");
    double growth = Lib.Proto.GetDouble(m, "growth");
    float lamps = Lib.Proto.GetFloat(m, "lamps");
    double lighting = Lib.Proto.GetDouble(m, "lighting");

    // if lamp is on
    if (lamps > float.Epsilon)
    {
      // get resource handler
      resource_info ec = resources.Info(vessel, "ElectricCharge");

      // consume ec
      ec.Consume(greenhouse.ec_rate * lamps * elapsed_s * Reliability.Penalty(p, "Greenhouse", 2.0));

      // shut down the light if there isn't enough ec
      // note: comparing against amount at previous simulation step
      if (ec.amount <= double.Epsilon) lamps = 0.0f;
    }

    // determine lighting conditions
    // note: we ignore sun direction for gameplay reasons: else the user must reorient the greenhouse as the planets dance over time
    // - natural light depend on: distance from sun, direct sunlight, door status
    // - artificial light depend on: lamps tweakable and ec available, door status
    lighting = info.solar_flux / Sim.SolarFluxAtHome() * (door_opened ? 1.0 : 0.0) + lamps;

    // if can use waste, and there is some lighting
    double waste_perc = 0.0;
    if (greenhouse.waste_name.Length > 0 && lighting > double.Epsilon)
    {
      // get resource handler
      resource_info waste = resources.Info(vessel, greenhouse.waste_name);

      // consume waste
      waste.Consume(greenhouse.waste_rate * elapsed_s);

      // determine waste bonus
      // note: comparing against amount from previous simulation step
      waste_perc = Math.Min(waste.amount / greenhouse.waste_rate, 1.0);
    }

    // determine growth bonus
    double growth_bonus = greenhouse.soil_bonus * (info.landed ? 1.0 : 0.0) + greenhouse.waste_bonus * waste_perc;

    // grow the crop
    double growing = greenhouse.growth_rate * (1.0 + growth_bonus) * lighting;
    growth += elapsed_s * growing;

    // if it is harvest time
    if (growth >= 1.0)
    {
      // reset growth
      growth = 0.0;

      // produce food
      resources.Produce(vessel, greenhouse.resource_name, greenhouse.harvest_size);

      // show a message to the user
      Message.Post(Lib.BuildString("On <color=FFFFFF>", vessel.vesselName, "</color> the crop harvest produced <color=FFFFFF>",
        greenhouse.harvest_size.ToString("F0"), " ", greenhouse.resource_name, "</color>"));

      // record first space harvest
      if (!info.landed && DB.Ready()) DB.Landmarks().space_harvest = 1;
    }

    // store data
    Lib.Proto.Set(m, "growth", growth);
    Lib.Proto.Set(m, "lamps", lamps);
    Lib.Proto.Set(m, "lighting", lighting);
    Lib.Proto.Set(m, "growth_diff", growing);
  }
Ejemplo n.º 13
0
  // called at every simulation step
  public void FixedUpdate()
  {
    // do nothing if paused
    if (Lib.IsPaused()) return;

    // do nothing if DB isn't ready
    if (!DB.Ready()) return;

    // for each vessel
    foreach(Vessel vessel in FlightGlobals.Vessels)
    {
      // skip invalid vessels
      if (!Lib.IsVessel(vessel)) continue;

      // skip loaded vessels
      if (vessel.loaded) continue;

      // get vessel data from the db
      vessel_data vd = DB.VesselData(vessel.id);

      // get vessel info from the cache
      vessel_info info = Cache.VesselInfo(vessel);

      // calculate atmospheric factor (proportion of flux not blocked by atmosphere)
      double atmo_factor = Sim.AtmosphereFactor(vessel.mainBody, info.position, info.sun_dir);

      // for each part
      foreach(ProtoPartSnapshot part in vessel.protoVessel.protoPartSnapshots)
      {
        // get part prefab (required for module properties)
        Part part_prefab = PartLoader.getPartInfoByName(part.partName).partPrefab;

        // store index of ModuleResourceConverter to process
        // rationale: a part can contain multiple resource converters
        int converter_index = 0;

        // for each module
        foreach(ProtoPartModuleSnapshot module in part.modules)
        {
          // something weird is going on, skip this
          if (!part_prefab.Modules.Contains(module.moduleName)) continue;

          // command module
          if (module.moduleName == "ModuleCommand")
          {
            // get module from prefab
            ModuleCommand command = part_prefab.Modules.GetModules<ModuleCommand>()[0];

            // do not consume if this is a MCM with no crew
            // rationale: for consistency, the game doesn't consume resources for MCM without crew in loaded vessels
            //            this make some sense: you left a vessel with some battery and nobody on board, you expect it to not consume EC
            if (command.minimumCrew == 0 || part.protoModuleCrew.Count > 0)
            {
              // for each input resource
              foreach(ModuleResource ir in command.inputResources)
              {
                // consume the resource
                Lib.RequestResource(vessel, ir.name, ir.rate * TimeWarp.fixedDeltaTime);
              }
            }
          }
          // solar panel
          else if (module.moduleName == "ModuleDeployableSolarPanel")
          {
            // determine if extended
            bool extended = module.moduleValues.GetValue("stateString") == ModuleDeployableSolarPanel.panelStates.EXTENDED.ToString();

            // if in sunlight and extended
            if (info.sunlight && extended)
            {
              // get module from prefab
              ModuleDeployableSolarPanel panel = part_prefab.Modules.GetModules<ModuleDeployableSolarPanel>()[0];

              // produce electric charge
              Lib.RequestResource(vessel, "ElectricCharge", -PanelOutput(vessel, part, panel, info.sun_dir, info.sun_dist, atmo_factor) * TimeWarp.fixedDeltaTime * Malfunction.Penalty(part));
            }
          }
          // generator
          // note: assume generators require all input
          else if (module.moduleName == "ModuleGenerator")
          {
            // determine if active
            bool activated = Convert.ToBoolean(module.moduleValues.GetValue("generatorIsActive"));

            // if active
            if (activated)
            {
              // get module from prefab
              ModuleGenerator generator = part_prefab.Modules.GetModules<ModuleGenerator>()[0];

              // determine if vessel is full of all output resources
              bool full = true;
              foreach(var or in generator.outputList)
              {
                double amount = Lib.GetResourceAmount(vessel, or.name);
                double capacity = Lib.GetResourceCapacity(vessel, or.name);
                double perc = capacity > 0.0 ? amount / capacity : 0.0;
                full &= (perc >= 1.0 - double.Epsilon);
              }

              // if not full
              if (!full)
              {
                // calculate worst required resource percentual
                double worst_input = 1.0;
                foreach(var ir in generator.inputList)
                {
                  double required = ir.rate * TimeWarp.fixedDeltaTime;
                  double amount = Lib.GetResourceAmount(vessel, ir.name);
                  worst_input = Math.Min(worst_input, amount / required);
                }

                // for each input resource
                foreach(var ir in generator.inputList)
                {
                  // consume the resource
                  Lib.RequestResource(vessel, ir.name, ir.rate * worst_input * TimeWarp.fixedDeltaTime);
                }

                // for each output resource
                foreach(var or in generator.outputList)
                {
                  // produce the resource
                  Lib.RequestResource(vessel, or.name, -or.rate * worst_input * TimeWarp.fixedDeltaTime * Malfunction.Penalty(part));
                }
              }
            }
          }
          // converter
          // note: support multiple resource converters
          // note: ignore stock temperature mechanic of converters
          // note: ignore autoshutdown
          // note: ignore crew experience bonus (seem that stock ignore it too)
          // note: 'undo' stock behaviour by forcing lastUpdateTime to now (to minimize overlapping calculations from this and stock post-facto simulation)
          // note: support PlanetaryBaseSystem converters
          // note: support NearFuture reactors
          else if (module.moduleName == "ModuleResourceConverter" || module.moduleName == "ModuleKPBSConverter" || module.moduleName == "FissionReactor")
          {
            // get module from prefab
            ModuleResourceConverter converter = part_prefab.Modules.GetModules<ModuleResourceConverter>()[converter_index++];

            // determine if active
            bool activated = Convert.ToBoolean(module.moduleValues.GetValue("IsActivated"));

            // if active
            if (activated)
            {
              // determine if vessel is full of all output resources
              bool full = true;
              foreach(var or in converter.outputList)
              {
                double amount = Lib.GetResourceAmount(vessel, or.ResourceName);
                double capacity = Lib.GetResourceCapacity(vessel, or.ResourceName);
                double perc = capacity > 0.0 ? amount / capacity : 0.0;
                full &= (perc >= converter.FillAmount - double.Epsilon);
              }

              // if not full
              if (!full)
              {
                // calculate worst required resource percentual
                double worst_input = 1.0;
                foreach(var ir in converter.inputList)
                {
                  double required = ir.Ratio * TimeWarp.fixedDeltaTime;
                  double amount = Lib.GetResourceAmount(vessel, ir.ResourceName);
                  worst_input = Math.Min(worst_input, amount / required);
                }

                // for each input resource
                foreach(var ir in converter.inputList)
                {
                  // consume the resource
                  Lib.RequestResource(vessel, ir.ResourceName, ir.Ratio * worst_input * TimeWarp.fixedDeltaTime);
                }

                // for each output resource
                foreach(var or in converter.outputList)
                {
                  // produce the resource
                  Lib.RequestResource(vessel, or.ResourceName, -or.Ratio * worst_input * TimeWarp.fixedDeltaTime * Malfunction.Penalty(part));
                }
              }

              // undo stock behaviour by forcing last_update_time to now
              module.moduleValues.SetValue("lastUpdateTime", Planetarium.GetUniversalTime().ToString());
            }
          }
          // drill
          // note: ignore stock temperature mechanic of harvesters
          // note: ignore autoshutdown
          // note: ignore depletion (stock seem to do the same)
          // note: 'undo' stock behaviour by forcing lastUpdateTime to now (to minimize overlapping calculations from this and stock post-facto simulation)
          else if (module.moduleName == "ModuleResourceHarvester")
          {
            // determine if active
            bool activated = Convert.ToBoolean(module.moduleValues.GetValue("IsActivated"));

            // if active
            if (activated)
            {
              // get module from prefab
              ModuleResourceHarvester harvester = part_prefab.Modules.GetModules<ModuleResourceHarvester>()[0];

              // [disabled] reason: not working
              // deduce crew bonus
              /*double experience_bonus = 0.0;
              if (harvester.UseSpecialistBonus)
              {
                foreach(ProtoCrewMember c in vessel.protoVessel.GetVesselCrew())
                {
                  experience_bonus = Math.Max(experience_bonus, (c.trait == harvester.Specialty) ? (double)c.experienceLevel : 0.0);
                }
              }*/
              const double crew_bonus = 1.0; //harvester.SpecialistBonusBase + (experience_bonus + 1.0) * harvester.SpecialistEfficiencyFactor;

              // detect amount of ore in the ground
              AbundanceRequest request = new AbundanceRequest
              {
                Altitude = vessel.altitude,
                BodyId = vessel.mainBody.flightGlobalsIndex,
                CheckForLock = false,
                Latitude = vessel.latitude,
                Longitude = vessel.longitude,
                ResourceType = (HarvestTypes)harvester.HarvesterType,
                ResourceName = harvester.ResourceName
              };
              double abundance = ResourceMap.Instance.GetAbundance(request);

              // if there is actually something (should be if active when unloaded)
              if (abundance > harvester.HarvestThreshold)
              {
                // calculate worst required resource percentual
                double worst_input = 1.0;
                foreach(var ir in harvester.inputList)
                {
                  double required = ir.Ratio * TimeWarp.fixedDeltaTime;
                  double amount = Lib.GetResourceAmount(vessel, ir.ResourceName);
                  worst_input = Math.Min(worst_input, amount / required);
                }

                // for each input resource
                foreach(var ir in harvester.inputList)
                {
                  // consume the resource
                  Lib.RequestResource(vessel, ir.ResourceName, ir.Ratio * worst_input * TimeWarp.fixedDeltaTime);
                }

                // determine resource produced
                double res = abundance * harvester.Efficiency * crew_bonus * worst_input * Malfunction.Penalty(part);

                // accumulate ore
                Lib.RequestResource(vessel, harvester.ResourceName, -res * TimeWarp.fixedDeltaTime);
              }

              // undo stock behaviour by forcing last_update_time to now
              module.moduleValues.SetValue("lastUpdateTime", Planetarium.GetUniversalTime().ToString());
            }
          }
          // asteroid drill
          // note: untested
          // note: ignore stock temperature mechanic of asteroid drills
          // note: ignore autoshutdown
          // note: 'undo' stock behaviour by forcing lastUpdateTime to now (to minimize overlapping calculations from this and stock post-facto simulation)
          else if (module.moduleName == "ModuleAsteroidDrill")
          {
            // determine if active
            bool activated = Convert.ToBoolean(module.moduleValues.GetValue("IsActivated"));

            // if active
            if (activated)
            {
              // get module from prefab
              ModuleAsteroidDrill asteroid_drill = part_prefab.Modules.GetModules<ModuleAsteroidDrill>()[0];

              // [disabled] reason: not working
              // deduce crew bonus
              /*double experience_bonus = 0.0;
              if (asteroid_drill.UseSpecialistBonus)
              {
                foreach(ProtoCrewMember c in vessel.protoVessel.GetVesselCrew())
                {
                  experience_bonus = Math.Max(experience_bonus, (c.trait == asteroid_drill.Specialty) ? (double)c.experienceLevel : 0.0);
                }
              }*/
              const double crew_bonus = 1.0; //asteroid_drill.SpecialistBonusBase + (experience_bonus + 1.0) * asteroid_drill.SpecialistEfficiencyFactor;

              // get asteroid data
              ProtoPartModuleSnapshot asteroid_info = null;
              ProtoPartModuleSnapshot asteroid_resource = null;
              foreach(ProtoPartSnapshot p in vessel.protoVessel.protoPartSnapshots)
              {
                if (asteroid_info == null) asteroid_info = p.modules.Find(k => k.moduleName == "ModuleAsteroidInfo");
                if (asteroid_resource == null) asteroid_resource = p.modules.Find(k => k.moduleName == "ModuleAsteroidResource");
              }

              // if there is actually an asteroid attached to this active asteroid drill (it should)
              if (asteroid_info != null && asteroid_resource != null)
              {
                // get some data
                double mass_threshold = Convert.ToDouble(asteroid_info.moduleValues.GetValue("massThresholdVal"));
                double mass = Convert.ToDouble(asteroid_info.moduleValues.GetValue("currentMassVal"));
                double abundance = Convert.ToDouble(asteroid_resource.moduleValues.GetValue("abundance"));
                string res_name = asteroid_resource.moduleValues.GetValue("resourceName");
                double res_density = PartResourceLibrary.Instance.GetDefinition(res_name).density;

                // if asteroid isn't depleted
                if (mass > mass_threshold && abundance > double.Epsilon)
                {
                  // consume EC
                  double ec_required = asteroid_drill.PowerConsumption * TimeWarp.fixedDeltaTime;
                  double ec_consumed = Lib.RequestResource(vessel, "ElectricCharge", ec_required);
                  double ec_ratio = ec_consumed / ec_required;

                  // determine resource extracted
                  double res_amount = abundance * asteroid_drill.Efficiency * crew_bonus * ec_ratio * TimeWarp.fixedDeltaTime;

                  // produce mined resource
                  Lib.RequestResource(vessel, res_name, -res_amount);

                  // consume asteroid mass
                  asteroid_info.moduleValues.SetValue("currentMassVal", (mass - res_density * res_amount).ToString());
                }
              }

              // undo stock behaviour by forcing last_update_time to now
              module.moduleValues.SetValue("lastUpdateTime", Planetarium.GetUniversalTime().ToString());
            }
          }
          // science lab
          // note: we are only simulating the EC consumption
          // note: there is no easy way to 'stop' the lab when there isn't enough EC
          else if (module.moduleName == "ModuleScienceConverter")
          {
            // get module from prefab
            ModuleScienceConverter lab = part_prefab.Modules.GetModules<ModuleScienceConverter>()[0];

            // determine if active
            bool activated = Convert.ToBoolean(module.moduleValues.GetValue("IsActivated"));

            // if active
            if (activated)
            {
              Lib.RequestResource(vessel, "ElectricCharge", lab.powerRequirement * TimeWarp.fixedDeltaTime);
            }
          }
          // SCANSAT support
          else if (module.moduleName == "SCANsat" || module.moduleName == "ModuleSCANresourceScanner")
          {
            // get ec consumption rate
            PartModule scansat = part_prefab.Modules[module.moduleName];
            double power = Lib.ReflectionValue<float>(scansat, "power");
            double ec_required = power * TimeWarp.fixedDeltaTime;
            bool is_scanning = Lib.GetProtoValue<bool>(module, "scanning");
            bool was_disabled = vd.scansat_id.Contains(part.flightID);

            // if its scanning
            if (Lib.GetProtoValue<bool>(module, "scanning"))
            {
              // consume ec
              double ec_consumed = Lib.RequestResource(vessel, "ElectricCharge", ec_required);

              // if there isn't enough ec
              if (ec_consumed < ec_required * 0.99 && ec_required > double.Epsilon)
              {
                // unregister scanner
                SCANsat.stopScanner(vessel, module, part_prefab);

                // remember disabled scanner
                vd.scansat_id.Add(part.flightID);

                // give the user some feedback
                if (DB.VesselData(vessel.id).cfg_ec == 1)
                  Message.Post("SCANsat sensor was disabled on <b>" + vessel.vesselName + "</b>");
              }
            }
            // if it was disabled
            else if (vd.scansat_id.Contains(part.flightID))
            {
              // if there is enough ec
              double ec_amount = Lib.GetResourceAmount(vessel, "ElectricCharge");
              double ec_capacity = Lib.GetResourceCapacity(vessel, "ElectricCharge");
              if (ec_capacity > double.Epsilon && ec_amount / ec_capacity > 0.25) //< re-enable at 25% EC
              {
                // re-enable the scanner
                SCANsat.resumeScanner(vessel, module, part_prefab);

                // give the user some feedback
                if (DB.VesselData(vessel.id).cfg_ec == 1)
                  Message.Post("SCANsat sensor resumed operations on <b>" + vessel.vesselName + "</b>");
              }
            }

            // forget active scanners
            if (Lib.GetProtoValue<bool>(module, "scanning")) vd.scansat_id.Remove(part.flightID);
          }
          // NearFutureSolar support
          // note: we assume deployed, this is a current limitation
          else if (module.moduleName == "ModuleCurvedSolarPanel")
          {
            // if in sunlight
            if (info.sunlight)
            {
              PartModule curved_panel = part_prefab.Modules[module.moduleName];
              double output = CurvedPanelOutput(vessel, part, part_prefab, curved_panel, info.sun_dir, info.sun_dist, atmo_factor) * Malfunction.Penalty(part);
              Lib.RequestResource(vessel, "ElectricCharge", -output * TimeWarp.fixedDeltaTime);
            }
          }
          // NearFutureElectrical support
          // note: fission generator ignore heat
          // note: radioisotope generator doesn't support easy mode
          else if (module.moduleName == "FissionGenerator")
          {
            PartModule generator = part_prefab.Modules[module.moduleName];
            double power = Lib.ReflectionValue<float>(generator, "PowerGeneration");

            // get fission reactor tweakable, will default to 1.0 for other modules
            var reactor = part.modules.Find(k => k.moduleName == "FissionReactor");
            double tweakable = reactor == null ? 1.0 : Lib.ConfigValue(reactor.moduleValues, "CurrentPowerPercent", 100.0) * 0.01;
            Lib.RequestResource(vessel, "ElectricCharge", -power * tweakable * TimeWarp.fixedDeltaTime);
          }
          else if (module.moduleName == "ModuleRadioisotopeGenerator")
          {
            double mission_time = vessel.missionTime / (3600.0 * Lib.HoursInDay() * Lib.DaysInYear());
            PartModule generator = part_prefab.Modules[module.moduleName];
            double half_life = Lib.ReflectionValue<float>(generator, "HalfLife");
            double remaining = Math.Pow(2.0, (-mission_time) / half_life);
            double power = Lib.ReflectionValue<float>(generator, "BasePower");
            Lib.RequestResource(vessel, "ElectricCharge", -power * remaining * TimeWarp.fixedDeltaTime);
          }
          // KERBALISM modules
          else if (module.moduleName == "Scrubber") { Scrubber.BackgroundUpdate(vessel, part.flightID); }
          else if (module.moduleName == "Greenhouse") { Greenhouse.BackgroundUpdate(vessel, part.flightID); }
          else if (module.moduleName == "GravityRing") { GravityRing.BackgroundUpdate(vessel, part.flightID); }
          else if (module.moduleName == "Malfunction") { Malfunction.BackgroundUpdate(vessel, part.flightID); }
        }
      }
    }
  }
Ejemplo n.º 14
0
  void render_info()
  {
    // find vessel
    Vessel v = FlightGlobals.Vessels.Find(k => k.id == vessel_id);

    // forget vessel if it doesn't exist anymore, or if its a dead eva kerbal
    if (v == null || EVA.IsDead(v)) { vessel_id = Guid.Empty; return; }

    // get info from the cache
    vessel_info vi = Cache.VesselInfo(v);

    render_title("ENVIRONMENT");
    render_content("Temperature:\t", Lib.HumanReadableTemp(vi.temperature));
    render_content("Radiation:\t", Lib.HumanReadableRadiationRate(vi.env_radiation));
    render_content("Atmosphere:\t", v.mainBody.atmosphere ? " yes" + (vi.breathable ? " <i>(breathable)</i>" : "") : "no");
    render_space();

    // render supplies
    if (Kerbalism.supply_rules.Count > 0 || Kerbalism.ec_rule != null)
    {
      render_title("SUPPLIES");
      if (Kerbalism.ec_rule != null)
      {
        var vmon = vi.vmon[Kerbalism.ec_rule.name];
        render_content(fix_title("Battery:"), vmon.level > double.Epsilon ? Lib.HumanReadableDuration(vmon.depletion) : "none");
      }
      if (Lib.CrewCapacity(v) > 0)
      {
        foreach(Rule r in Kerbalism.supply_rules)
        {
          var vmon = vi.vmon[r.name];
          render_content(fix_title(r.resource_name + ":"), vmon.level > double.Epsilon ? Lib.HumanReadableDuration(vmon.depletion) : "none");
        }
      }
      render_space();
    }


    // get crew
    var crew = v.loaded ? v.GetVesselCrew() : v.protoVessel.GetVesselCrew();

    // do not render internal spaces info for eva vessels
    if (!v.isEVA)
    {
      // collect set of spaces
      Dictionary<string, space_details> spaces = new Dictionary<string, space_details>();
      foreach(var c in crew)
      {
        kerbal_data kd = DB.KerbalData(c.name);
        if (!spaces.ContainsKey(kd.space_name))
        {
          space_details sd = new space_details();
          sd.living_space = kd.living_space;
          sd.entertainment = kd.entertainment;
          sd.shielding = kd.shielding;
          spaces.Add(kd.space_name, sd);
        }
        ++(spaces[kd.space_name].crew_count);
      }

      // for each space
      foreach(var space in spaces)
      {
        string space_name = space.Key;
        space_details det = space.Value;

        string radiation_txt = vi.env_radiation > double.Epsilon
          ? " <i>(" + Lib.HumanReadableRadiationRate(vi.env_radiation * (1.0 - det.shielding)) + ")</i>"
          : "";

        render_title(space_name.Length > 0 ? space_name.ToUpper() : v.isEVA ? "EVA" : "VESSEL");
        render_content("Living space:\t", QualityOfLife.LivingSpaceToString(det.living_space));
        render_content("Entertainment:\t", QualityOfLife.EntertainmentToString(det.entertainment));
        render_content("Shielding:\t", Radiation.ShieldingToString(det.shielding) + radiation_txt);
        render_space();
      }
    }

    // for each kerbal
    if (Kerbalism.rules.Count > 0)
    {
      foreach(var c in crew)
      {
        kerbal_data kd = DB.KerbalData(c.name);
        render_title(c.name.ToUpper());
        foreach(var q in Kerbalism.rules)
        {
          Rule r = q.Value;
          if (r.degeneration > double.Epsilon)
          {
            var kmon = DB.KmonData(c.name, r.name);
            var bar = Lib.ProgressBar(23, kmon.problem, r.warning_threshold, r.danger_threshold, r.fatal_threshold, kd.disabled > 0 ? "cyan" : "");
            render_content(fix_title(r.name + ":"), bar);
          }
        }
        if (kd.space_name.Length > 0 && !v.isEVA) render_content("Inside:\t\t", kd.space_name);
        if (kd.disabled > 0) render_content("Hibernated:\t", "yes");
        render_space();
      }
    }

    // for each greenhouse
    var greenhouses = Greenhouse.GetGreenhouses(v);
    foreach(var greenhouse in greenhouses)
    {
      render_title("GREENHOUSE");
      render_content("Lighting:\t\t", (greenhouse.lighting * 100.0).ToString("F0") + "%");
      render_content("Growth:\t\t", (greenhouse.growth * 100.0).ToString("F0") + "%");
      render_content("Harvest:\t\t", Lib.HumanReadableDuration(greenhouse.growing > double.Epsilon ? 1.0 / greenhouse.growing : 0.0));
      render_space();
    }
  }
Ejemplo n.º 15
0
        public static void update(Vessel v, vessel_info vi, VesselData vd, vessel_resources resources, double elapsed_s)
        {
            // get most used resource handlers
            resource_info ec = resources.Info(v, "ElectricCharge");

            // store data required to support multiple modules of same type in a part
            var PD = new Dictionary <string, Lib.module_prefab_data>();

            // for each part
            foreach (ProtoPartSnapshot p in v.protoVessel.protoPartSnapshots)
            {
                // get part prefab (required for module properties)
                Part part_prefab = PartLoader.getPartInfoByName(p.partName).partPrefab;

                // get all module prefabs
                var module_prefabs = part_prefab.FindModulesImplementing <PartModule>();

                // clear module indexes
                PD.Clear();

                // for each module
                foreach (ProtoPartModuleSnapshot m in p.modules)
                {
                    // get module type
                    // if the type is unknown, skip it
                    module_type type = ModuleType(m.moduleName);
                    if (type == module_type.Unknown)
                    {
                        continue;
                    }

                    // get the module prefab
                    // if the prefab doesn't contain this module, skip it
                    PartModule module_prefab = Lib.ModulePrefab(module_prefabs, m.moduleName, PD);
                    if (!module_prefab)
                    {
                        continue;
                    }

                    // if the module is disabled, skip it
                    // note: this must be done after ModulePrefab is called, so that indexes are right
                    if (!Lib.Proto.GetBool(m, "isEnabled"))
                    {
                        continue;
                    }

                    // process modules
                    // note: this should be a fast switch, possibly compiled to a jump table
                    switch (type)
                    {
                    case module_type.Reliability:           Reliability.BackgroundUpdate(v, p, m, module_prefab as Reliability);                        break;

                    case module_type.Experiment:            Experiment.BackgroundUpdate(v, m, module_prefab as Experiment, ec, elapsed_s);              break;

                    case module_type.Greenhouse:            Greenhouse.BackgroundUpdate(v, m, module_prefab as Greenhouse, vi, resources, elapsed_s);   break;

                    case module_type.GravityRing:           GravityRing.BackgroundUpdate(v, p, m, module_prefab as GravityRing, ec, elapsed_s);         break;

                    case module_type.Emitter:               Emitter.BackgroundUpdate(v, p, m, module_prefab as Emitter, ec, elapsed_s);                 break;

                    case module_type.Harvester:             Harvester.BackgroundUpdate(v, m, module_prefab as Harvester, elapsed_s);                    break;

                    case module_type.Laboratory:            Laboratory.BackgroundUpdate(v, p, m, module_prefab as Laboratory, ec, elapsed_s);           break;

                    case module_type.Command:               ProcessCommand(v, p, m, module_prefab as ModuleCommand, resources, elapsed_s);              break;

                    case module_type.Panel:                 ProcessPanel(v, p, m, module_prefab as ModuleDeployableSolarPanel, vi, ec, elapsed_s);      break;

                    case module_type.Generator:             ProcessGenerator(v, p, m, module_prefab as ModuleGenerator, resources, elapsed_s);          break;

                    case module_type.Converter:             ProcessConverter(v, p, m, module_prefab as ModuleResourceConverter, resources, elapsed_s);  break;

                    case module_type.Drill:                 ProcessHarvester(v, p, m, module_prefab as ModuleResourceHarvester, resources, elapsed_s);  break;

                    case module_type.AsteroidDrill:         ProcessAsteroidDrill(v, p, m, module_prefab as ModuleAsteroidDrill, resources, elapsed_s);  break;

                    case module_type.StockLab:              ProcessStockLab(v, p, m, module_prefab as ModuleScienceConverter, ec, elapsed_s);           break;

                    case module_type.Light:                 ProcessLight(v, p, m, module_prefab as ModuleLight, ec, elapsed_s);                         break;

                    case module_type.Scanner:               ProcessScanner(v, p, m, module_prefab, part_prefab, vd, ec, elapsed_s);                     break;

                    case module_type.CurvedPanel:           ProcessCurvedPanel(v, p, m, module_prefab, part_prefab, vi, ec, elapsed_s);                 break;

                    case module_type.FissionGenerator:      ProcessFissionGenerator(v, p, m, module_prefab, ec, elapsed_s);                             break;

                    case module_type.RadioisotopeGenerator: ProcessRadioisotopeGenerator(v, p, m, module_prefab, ec, elapsed_s);                        break;

                    case module_type.CryoTank:              ProcessCryoTank(v, p, m, module_prefab, resources, elapsed_s);                              break;
                    }
                }
            }
        }
Ejemplo n.º 16
0
  public vessel_info(Vessel v, uint vessel_id, UInt64 inc)
  {
    // NOTE: anything used here can't in turn use cache, unless you know what you are doing

    // NOTE: you can't cache vessel position
    // at any point in time all vessel/body positions are relative to a different frame of reference
    // so comparing the current position of a vessel, with the cached one of another make no sense

    // associate with an unique incremental id
    this.inc = inc;

    // determine if this is a valid vessel
    is_vessel = Lib.IsVessel(v);
    if (!is_vessel) return;

    // determine if this is a rescue mission vessel
    is_rescue = Misc.IsRescueMission(v);
    if (is_rescue) return;

    // dead EVA are not valid vessels
    if (EVA.IsDead(v)) return;

    // shortcut for common tests
    is_valid = true;

    // generate id once
    id = vessel_id;

    // calculate crew info for the vessel
    crew_count = Lib.CrewCount(v);
    crew_capacity = Lib.CrewCapacity(v);

    // get vessel position
    Vector3d position = Lib.VesselPosition(v);

    // this should never happen again
    if (Vector3d.Distance(position, v.mainBody.position) < 1.0)
    {
      throw new Exception("Shit hit the fan for vessel " + v.vesselName);
    }

    // determine if in sunlight, calculate sun direction and distance
    sunlight = Sim.RaytraceBody(v, position, FlightGlobals.Bodies[0], out sun_dir, out sun_dist) ? 1.0 : 0.0;

    // at the two highest timewarp speed, the number of sun visibility samples drop to the point that
    // the quantization error first became noticeable, and then exceed 100%
    // to solve this, we switch to an analytical estimation of the portion of orbit that was in sunlight
    // - we check against timewarp rate, instead of index, to avoid issues during timewarp blending
    if (v.mainBody.flightGlobalsIndex != 0 && TimeWarp.CurrentRate > 1000.0f)
    {
      sunlight = 1.0 - Sim.ShadowPeriod(v) / Sim.OrbitalPeriod(v);
    }

    // environment stuff
    atmo_factor = Sim.AtmosphereFactor(v.mainBody, position, sun_dir);
    gamma_transparency = Sim.GammaTransparency(v.mainBody, v.altitude);
    underwater = Sim.Underwater(v);
    breathable = Sim.Breathable(v, underwater);
    landed = Lib.Landed(v);

    // temperature at vessel position
    temperature = Sim.Temperature(v, position, sunlight, atmo_factor, out solar_flux, out albedo_flux, out body_flux, out total_flux);
    temp_diff = Sim.TempDiff(temperature, v.mainBody, landed);

    // radiation
    radiation = Radiation.Compute(v, position, gamma_transparency, sunlight, out blackout, out magnetosphere, out inner_belt, out outer_belt, out interstellar);

    // extended atmosphere
    thermosphere = Sim.InsideThermosphere(v);
    exosphere = Sim.InsideExosphere(v);

    // malfunction stuff
    malfunction = Reliability.HasMalfunction(v);
    critical = Reliability.HasCriticalFailure(v);

    // signal info
    antenna = new AntennaInfo(v);
    avoid_inf_recursion.Add(v.id);
    connection = Signal.connection(v, position, antenna, blackout, avoid_inf_recursion);
    transmitting = Science.transmitting(v, connection.linked);
    relaying = Signal.relaying(v, avoid_inf_recursion);
    avoid_inf_recursion.Remove(v.id);

    // habitat data
    volume = Habitat.tot_volume(v);
    surface = Habitat.tot_surface(v);
    pressure = Habitat.pressure(v);
    poisoning = Habitat.poisoning(v);
    shielding = Habitat.shielding(v);
    living_space = Habitat.living_space(v);
    comforts = new Comforts(v, landed, crew_count > 1, connection.linked);

    // data about greenhouses
    greenhouses = Greenhouse.Greenhouses(v);

    // other stuff
    gravioli = Sim.Graviolis(v);
  }
Ejemplo n.º 17
0
        public static void update(Vessel v, vessel_info vi, vessel_data vd, vessel_resources resources, double elapsed_s)
        {
            // get most used resource handlers
            resource_info ec = resources.Info(v, "ElectricCharge");

            // for each part
            foreach (ProtoPartSnapshot p in v.protoVessel.protoPartSnapshots)
            {
                // a part can contain multiple resource converters
                int converter_index = 0;

                // get part prefab (required for module properties)
                Part part_prefab = PartLoader.getPartInfoByName(p.partName).partPrefab;

                // for each module
                foreach (ProtoPartModuleSnapshot m in p.modules)
                {
                    // get the module prefab
                    PartModule module_prefab = Lib.FindModule(part_prefab, m.moduleName);

                    // if the prefab doesn't contain this module, skip it
                    if (!module_prefab)
                    {
                        continue;
                    }

                    // process modules
                    switch (m.moduleName)
                    {
                    case "Reliability":                  Reliability.BackgroundUpdate(v, m, module_prefab as Reliability, elapsed_s);                 break;

                    case "Scrubber":                     Scrubber.BackgroundUpdate(v, m, module_prefab as Scrubber, vi, resources, elapsed_s);        break;

                    case "Recycler":                     Recycler.BackgroundUpdate(v, m, module_prefab as Recycler, resources, elapsed_s);            break;

                    case "Greenhouse":                   Greenhouse.BackgroundUpdate(v, p, m, module_prefab as Greenhouse, vi, resources, elapsed_s); break;

                    case "GravityRing":                  GravityRing.BackgroundUpdate(v, p, m, module_prefab as GravityRing, resources, elapsed_s);   break;

                    case "Emitter":                      Emitter.BackgroundUpdate(v, p, m, module_prefab as Emitter, ec, elapsed_s);                  break;

                    case "ModuleCommand":                ProcessCommand(v, p, m, module_prefab as ModuleCommand, resources, elapsed_s);               break;

                    case "ModuleDeployableSolarPanel":   ProcessPanel(v, p, m, module_prefab as ModuleDeployableSolarPanel, vi, ec, elapsed_s);       break;

                    case "ModuleGenerator":              ProcessGenerator(v, p, m, module_prefab as ModuleGenerator, resources, elapsed_s);           break;

                    case "ModuleResourceConverter":
                    case "ModuleKPBSConverter":
                    case "FissionReactor":               ProcessConverter(v, p, m, part_prefab, converter_index++, resources, elapsed_s);             break;

                    case "ModuleResourceHarvester":      ProcessHarvester(v, p, m, module_prefab as ModuleResourceHarvester, resources, elapsed_s);   break;

                    case "ModuleAsteroidDrill":          ProcessAsteroidDrill(v, p, m, module_prefab as ModuleAsteroidDrill, resources, elapsed_s);   break;

                    case "ModuleScienceConverter":       ProcessLab(v, p, m, module_prefab as ModuleScienceConverter, ec, elapsed_s);                 break;

                    case "ModuleLight":
                    case "ModuleColoredLensLight":
                    case "ModuleMultiPointSurfaceLight": ProcessLight(v, p, m, module_prefab as ModuleLight, ec, elapsed_s);                          break;

                    case "SCANsat":
                    case "ModuleSCANresourceScanner":    ProcessScanner(v, p, m, module_prefab, part_prefab, vd, ec, elapsed_s);                      break;

                    case "ModuleCurvedSolarPanel":       ProcessCurvedPanel(v, p, m, module_prefab, part_prefab, vi, ec, elapsed_s);                  break;

                    case "FissionGenerator":             ProcessFissionGenerator(v, p, m, module_prefab, ec, elapsed_s);                              break;

                    case "ModuleRadioisotopeGenerator":  ProcessRadioisotopeGenerator(v, p, m, module_prefab, ec, elapsed_s);                         break;

                    case "ModuleCryoTank":               ProcessCryoTank(v, p, m, module_prefab, resources, elapsed_s);                               break;
                    }
                }
            }
        }
Ejemplo n.º 18
0
  public static food_data analyze_food(List<Part> parts, environment_data env, crew_data crew)
  {
    // store data
    food_data food = new food_data();

    // calculate food consumed
    food.consumed = (double)crew.count * Settings.FoodPerMeal / Settings.MealFrequency;

    // deduce waste produced by the crew per-second
    double simulated_waste = food.consumed;

    // scan the parts
    foreach(Part p in parts)
    {
      // accumulate food storage
      food.storage += Lib.GetResourceAmount(p, "Food");

      // for each module
      foreach(PartModule m in p.Modules)
      {
        // greenhouse
        if (m.moduleName == "Greenhouse")
        {
          Greenhouse mm = (Greenhouse)m;

          // calculate natural lighting
          double natural_lighting = Greenhouse.NaturalLighting(env.sun_dist);

          // calculate ec consumed
          food.greenhouse_cost += mm.ec_rate * mm.lamps;

          // calculate lighting
          double lighting = natural_lighting * (mm.door_opened ? 1.0 : 0.0) + mm.lamps * (mm.door_opened ? 1.0 : 1.0 + Settings.GreenhouseDoorBonus);

          // calculate waste used
          double waste_used = Math.Min(simulated_waste, mm.waste_rate);
          double waste_perc = waste_used / mm.waste_rate;
          simulated_waste -= waste_used;

          // calculate growth bonus
          double growth_bonus = 0.0;
          growth_bonus += Settings.GreenhouseSoilBonus * (env.landed ? 1.0 : 0.0);
          growth_bonus += Settings.GreenhouseWasteBonus * waste_perc;

          // calculate growth factor
          double growth_factor = (mm.growth_rate * (1.0 + growth_bonus)) * lighting;

          // calculate food cultivated
          food.cultivated += mm.harvest_size * growth_factor;

          // calculate time-to-harvest
          if (growth_factor > double.Epsilon)
          {
            food.cultivated_tooltip += (food.cultivated_tooltip.Length > 0 ? "\n" : "")
              + "Time-to-harvest: <b>" + Lib.HumanReadableDuration(1.0 / growth_factor) + "</b>";
          }
        }
      }
    }

    // calculate life expectancy
    food.life_expectancy = food.storage / Math.Max(food.consumed - food.cultivated, 0.0);

    // add formatting to tooltip
    if (food.cultivated_tooltip.Length > 0) food.cultivated_tooltip = "<i>" + food.cultivated_tooltip + "</i>";

    // return data
    return food;
  }