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"); // 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; } } }
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; // Kerbalism ground and air harvester module 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: ProcessDrill(v, p, m, module_prefab as ModuleResourceHarvester, resources, elapsed_s); break; // Stock ground harvester module case Module_type.AsteroidDrill: ProcessAsteroidDrill(v, p, m, module_prefab as ModuleAsteroidDrill, resources, elapsed_s); break; // Stock asteroid harvester module 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, ec, elapsed_s); break; case Module_type.FNGenerator: ProcessFNGenerator(v, p, m, module_prefab, ec, elapsed_s); break; } } } }
public ExperimentDevice(Experiment exp) { this.experiment = exp; this.exp_name = (exp.sample_mass < float.Epsilon ? "sensor" : "experiment") + ": " + Lib.SpacesOnCaps(ResearchAndDevelopment.GetExperiment(exp.experiment_id).experimentTitle).ToLower().Replace("e v a", "eva"); }
private static string TestForIssues(Vessel v, Resource_info ec, Experiment experiment, uint hdId, bool broken, double remainingSampleMass, bool didPrepare, bool isShrouded, bool noGroundContact, string last_subject_id) { var subject_id = Science.Generate_subject_id(experiment.experiment_id, v); if (broken) { return("broken"); } if (isShrouded && !experiment.allow_shrouded) { return("shrouded"); } bool needsReset = experiment.crew_reset.Length > 0 && !string.IsNullOrEmpty(last_subject_id) && subject_id != last_subject_id; if (needsReset) { return("reset required"); } if (ec.amount < double.Epsilon && experiment.ec_rate > double.Epsilon) { return("no Electricity"); } if (!string.IsNullOrEmpty(experiment.crew_operate)) { var cs = new CrewSpecs(experiment.crew_operate); if (!cs && Lib.CrewCount(v) > 0) { return("crew on board"); } else if (cs && !cs.Check(v)) { return(cs.Warning()); } } if (!experiment.sample_collecting && remainingSampleMass < double.Epsilon && experiment.sample_mass > double.Epsilon) { return("depleted"); } if (!didPrepare && !string.IsNullOrEmpty(experiment.crew_prepare)) { return("not prepared"); } if (noGroundContact) { return("no ground contact"); } string situationIssue = Science.TestRequirements(experiment.experiment_id, experiment.requires, v); if (situationIssue.Length > 0) { return(Science.RequirementText(situationIssue)); } var experimentSize = Science.Experiment(subject_id).max_amount; double chunkSize = Math.Min(experiment.data_rate * Kerbalism.elapsed_s, experimentSize); Drive drive = GetDrive(experiment, v, hdId, chunkSize, subject_id); var isFile = experiment.sample_mass < double.Epsilon; double available = 0; if (isFile) { available = drive.FileCapacityAvailable(); available += Cache.WarpCache(v).FileCapacityAvailable(); } else { available = drive.SampleCapacityAvailable(subject_id); } if (Math.Min(experiment.data_rate * Kerbalism.elapsed_s, experimentSize) > available) { return(insufficient_storage); } return(string.Empty); }
public static void BackgroundUpdate(Vessel v, ProtoPartModuleSnapshot m, Experiment experiment, Resource_info ec, Vessel_resources resources, double elapsed_s) { bool didPrepare = Lib.Proto.GetBool(m, "didPrepare", false); bool shrouded = Lib.Proto.GetBool(m, "shrouded", false); string last_subject_id = Lib.Proto.GetString(m, "last_subject_id", ""); double remainingSampleMass = Lib.Proto.GetDouble(m, "remainingSampleMass", 0); bool broken = Lib.Proto.GetBool(m, "broken", false); bool noGroundContact = Lib.Proto.GetBool(m, "noGroundContact", false); bool forcedRun = Lib.Proto.GetBool(m, "forcedRun", false); bool recording = Lib.Proto.GetBool(m, "recording", false); uint privateHdId = Lib.Proto.GetUInt(m, "privateHdId", 0); string issue = TestForIssues(v, ec, experiment, privateHdId, broken, remainingSampleMass, didPrepare, shrouded, noGroundContact, last_subject_id); if (string.IsNullOrEmpty(issue)) { issue = TestForResources(v, KerbalismProcess.ParseResources(experiment.resources), elapsed_s, resources); } Lib.Proto.Set(m, "issue", issue); if (!string.IsNullOrEmpty(issue)) { return; } var subject_id = Science.Generate_subject_id(experiment.experiment_id, v); Lib.Proto.Set(m, "last_subject_id", subject_id); double dataSampled = Lib.Proto.GetDouble(m, "dataSampled"); if (last_subject_id != subject_id) { dataSampled = 0; Lib.Proto.Set(m, "forcedRun", false); } double scienceValue = Science.Value(last_subject_id); Lib.Proto.Set(m, "scienceValue", scienceValue); var state = GetState(scienceValue, issue, recording, forcedRun); if (state != State.RUNNING) { return; } if (dataSampled >= Science.Experiment(subject_id).max_amount) { return; } var stored = DoRecord(experiment, subject_id, v, ec, privateHdId, resources, KerbalismProcess.ParseResources(experiment.resources), remainingSampleMass, dataSampled, out dataSampled, out remainingSampleMass); if (!stored) { Lib.Proto.Set(m, "issue", insufficient_storage); } Lib.Proto.Set(m, "dataSampled", dataSampled); Lib.Proto.Set(m, "remainingSampleMass", remainingSampleMass); }
private static bool DoRecord(Experiment experiment, string subject_id, Vessel vessel, Resource_info ec, uint hdId, Vessel_resources resources, List <KeyValuePair <string, double> > resourceDefs, double remainingSampleMass, double dataSampled, out double sampledOut, out double remainingSampleMassOut) { // default output values for early returns sampledOut = dataSampled; remainingSampleMassOut = remainingSampleMass; var exp = Science.Experiment(subject_id); if (Done(exp, dataSampled)) { return(true); } double elapsed = Kerbalism.elapsed_s; double chunkSize = Math.Min(experiment.data_rate * elapsed, exp.max_amount); double massDelta = experiment.sample_mass * chunkSize / exp.max_amount; Drive drive = GetDrive(experiment, vessel, hdId, chunkSize, subject_id); // on high time warp this chunk size could be too big, but we could store a sizable amount if we process less bool isFile = experiment.sample_mass < float.Epsilon; double maxCapacity = isFile ? drive.FileCapacityAvailable() : drive.SampleCapacityAvailable(subject_id); Drive warpCacheDrive = null; if (isFile) { if (drive.GetFileSend(subject_id)) { warpCacheDrive = Cache.WarpCache(vessel); } if (warpCacheDrive != null) { maxCapacity += warpCacheDrive.FileCapacityAvailable(); } } double factor = Rate(vessel, chunkSize, maxCapacity, elapsed, ec, experiment.ec_rate, resources, resourceDefs); if (factor < double.Epsilon) { return(false); } chunkSize *= factor; massDelta *= factor; elapsed *= factor; bool stored = false; if (chunkSize > double.Epsilon) { if (isFile) { if (warpCacheDrive != null) { double s = Math.Min(chunkSize, warpCacheDrive.FileCapacityAvailable()); stored = warpCacheDrive.Record_file(subject_id, s, true); if (chunkSize > s) // only write to persisted drive if the data cannot be transmitted in this tick { stored &= drive.Record_file(subject_id, chunkSize - s, true); } } else { stored = drive.Record_file(subject_id, chunkSize, true); } } else { stored = drive.Record_sample(subject_id, chunkSize, massDelta); } } if (!stored) { return(false); } // consume resources ec.Consume(experiment.ec_rate * elapsed, "experiment"); foreach (var p in resourceDefs) { resources.Consume(vessel, p.Key, p.Value * elapsed, "experiment"); } dataSampled += chunkSize; dataSampled = Math.Min(dataSampled, exp.max_amount); sampledOut = dataSampled; if (!experiment.sample_collecting) { remainingSampleMass -= massDelta; remainingSampleMass = Math.Max(remainingSampleMass, 0); } remainingSampleMassOut = remainingSampleMass; return(true); }
public ExperimentDevice(Experiment exp) { this.exp = exp; this.exp_name = Lib.SpacesOnCaps(ResearchAndDevelopment.GetExperiment(exp.experiment).experimentTitle).ToLower().Replace("e v a", "eva"); }