示例#1
0
        public override bool CitizenCanGo(uint citizenID, ref Citizen person)
        {
            bool canGo = false;

            if (m_eventChances != null && m_eventData.m_registeredCitizens < GetCapacity())
            {
                canGo = true;

                Citizen.Wealth    _citizenWealth    = person.WealthLevel;
                Citizen.Education _citizenEducation = person.EducationLevel;
                Citizen.Gender    _citizenGender    = Citizen.GetGender(citizenID);
                Citizen.Happiness _citizenHappiness = Citizen.GetHappinessLevel(Citizen.GetHappiness(person.m_health, person.m_wellbeing));
                Citizen.Wellbeing _citizenWellbeing = Citizen.GetWellbeingLevel(_citizenEducation, person.m_wellbeing);
                Citizen.AgeGroup  _citizenAgeGroup  = Citizen.GetAgeGroup(person.Age);

                float percentageChange = GetAdjustedChancePercentage();
                int   randomPercentage = Singleton <SimulationManager> .instance.m_randomizer.Int32(100U);

                switch (_citizenWealth)
                {
                case Citizen.Wealth.Low:
                    canGo = canGo && randomPercentage < Adjust(m_eventChances._lowWealth, percentageChange);
                    break;

                case Citizen.Wealth.Medium:
                    canGo = canGo && randomPercentage < Adjust(m_eventChances._mediumWealth, percentageChange);
                    break;

                case Citizen.Wealth.High:
                    canGo = canGo && randomPercentage < Adjust(m_eventChances._highWealth, percentageChange);
                    break;
                }

                randomPercentage = Singleton <SimulationManager> .instance.m_randomizer.Int32(100U);

                switch (_citizenEducation)
                {
                case Citizen.Education.Uneducated:
                    canGo = canGo && randomPercentage < Adjust(m_eventChances._uneducated, percentageChange);
                    break;

                case Citizen.Education.OneSchool:
                    canGo = canGo && randomPercentage < Adjust(m_eventChances._oneSchool, percentageChange);
                    break;

                case Citizen.Education.TwoSchools:
                    canGo = canGo && randomPercentage < Adjust(m_eventChances._twoSchools, percentageChange);
                    break;

                case Citizen.Education.ThreeSchools:
                    canGo = canGo && randomPercentage < Adjust(m_eventChances._threeSchools, percentageChange);
                    break;
                }

                randomPercentage = Singleton <SimulationManager> .instance.m_randomizer.Int32(100U);

                switch (_citizenGender)
                {
                case Citizen.Gender.Female:
                    canGo = canGo && randomPercentage < Adjust(m_eventChances._females, percentageChange);
                    break;

                case Citizen.Gender.Male:
                    canGo = canGo && randomPercentage < Adjust(m_eventChances._males, percentageChange);
                    break;
                }

                randomPercentage = Singleton <SimulationManager> .instance.m_randomizer.Int32(100U);

                switch (_citizenHappiness)
                {
                case Citizen.Happiness.Bad:
                    canGo = canGo && randomPercentage < Adjust(m_eventChances._badHappiness, percentageChange);
                    break;

                case Citizen.Happiness.Poor:
                    canGo = canGo && randomPercentage < Adjust(m_eventChances._poorHappiness, percentageChange);
                    break;

                case Citizen.Happiness.Good:
                    canGo = canGo && randomPercentage < Adjust(m_eventChances._goodHappiness, percentageChange);
                    break;

                case Citizen.Happiness.Excellent:
                    canGo = canGo && randomPercentage < Adjust(m_eventChances._excellentHappiness, percentageChange);
                    break;

                case Citizen.Happiness.Suberb:
                    canGo = canGo && randomPercentage < Adjust(m_eventChances._superbHappiness, percentageChange);
                    break;
                }

                randomPercentage = Singleton <SimulationManager> .instance.m_randomizer.Int32(100U);

                switch (_citizenWellbeing)
                {
                case Citizen.Wellbeing.VeryUnhappy:
                    canGo = canGo && randomPercentage < Adjust(m_eventChances._veryUnhappyWellbeing, percentageChange);
                    break;

                case Citizen.Wellbeing.Unhappy:
                    canGo = canGo && randomPercentage < Adjust(m_eventChances._unhappyWellbeing, percentageChange);
                    break;

                case Citizen.Wellbeing.Satisfied:
                    canGo = canGo && randomPercentage < Adjust(m_eventChances._satisfiedWellbeing, percentageChange);
                    break;

                case Citizen.Wellbeing.Happy:
                    canGo = canGo && randomPercentage < Adjust(m_eventChances._happyWellbeing, percentageChange);
                    break;

                case Citizen.Wellbeing.VeryHappy:
                    canGo = canGo && randomPercentage < Adjust(m_eventChances._veryHappyWellbeing, percentageChange);
                    break;
                }

                randomPercentage = Singleton <SimulationManager> .instance.m_randomizer.Int32(100U);

                switch (_citizenAgeGroup)
                {
                case Citizen.AgeGroup.Child:
                    canGo = canGo && randomPercentage < Adjust(m_eventChances._children, percentageChange);
                    break;

                case Citizen.AgeGroup.Teen:
                    canGo = canGo && randomPercentage < Adjust(m_eventChances._teens, percentageChange);
                    break;

                case Citizen.AgeGroup.Young:
                    canGo = canGo && randomPercentage < Adjust(m_eventChances._youngAdults, percentageChange);
                    break;

                case Citizen.AgeGroup.Adult:
                    canGo = canGo && randomPercentage < Adjust(m_eventChances._adults, percentageChange);
                    break;

                case Citizen.AgeGroup.Senior:
                    canGo = canGo && randomPercentage < Adjust(m_eventChances._seniors, percentageChange);
                    break;
                }

                CimTools.CimToolsHandler.CimToolBase.DetailedLogger.Log(
                    (canGo ? "[Can Go]" : "[Ignoring]") +
                    " Citizen " + citizenID + " for " + m_eventData.m_eventName + "\n\t" +
                    _citizenWealth.ToString() + ", " + _citizenEducation.ToString() + ", " + _citizenGender.ToString() + ", " +
                    _citizenHappiness.ToString() + ", " + _citizenWellbeing.ToString() + ", " + _citizenAgeGroup.ToString());
            }

            return(canGo);
        }
        /// <summary>
        /// Method called by OutsideConnectionAI.StartConnectionTransferImpl Transpiler insertion.
        /// Randomises (within parameters) age and education levels of immigrants.
        /// All variables are local variables within OutsideConnectionAI.StartConnectionTransferImpl.
        /// </summary>
        /// <param name="i">Loop counter (for loop containing method call)</param>
        /// <param name="education">Education level input (StartConnectionTransferImpl local variable)</param>
        /// <param name="ageArray">Array of acceptible ages (from mod DataStore); placed on stack in advance via Transpiler insertion</param>
        /// <param name="childrenAgeMax">Maximum child immigrant age; placed on stack in advance via Transpiler insertion </param>
        /// <param name="childrenAgeMin">Minimum child immigrant age; placed on stack in advance via Transpiler insertion</param>
        /// <param name="minAdultAge">Minimum adult immigrant age; placed on stack in advance via Transpiler insertion</param>
        /// <param name="resultEducation">Resultant education level for immigrant after mod calculations (StartConnectionTransferImpl local variable 'education2')</param>
        /// <param name="resultAge">Resultant age level for immigrant after mod calculations (StartConnectionTransferImpl local variable 'age')</param>
        public static void RandomizeImmigrants(int i, Citizen.Education education, int[] ageArray, ref int childrenAgeMax, ref int childrenAgeMin, ref int minAdultAge, out Citizen.Education resultEducation, out int resultAge)
        {
            // Minimum and maximum ages.
            int min = ageArray[0];
            int max = ageArray[1];

            // We start inside an i loop.
            // i is is the family member number for this incoming family.  0 is primary adult, 1 is secondary adults, and after that are children.
            if (i == 1)
            {
                // Age of second adult - shouldn't be too far from the first. Just because.
                min = Math.Max(minAdultAge - 20, DataStore.incomingAdultAge[0]);
                max = Math.Min(minAdultAge + 20, DataStore.incomingAdultAge[1]);
            }
            else if (i >= 2)
            {
                // Children.
                min = childrenAgeMin;
                max = childrenAgeMax;
            }

            // Calculate actual age randomly between minumum and maxiumum.
            resultAge = Singleton <SimulationManager> .instance.m_randomizer.Int32(min, max);

            // Adust age brackets for subsequent family members.
            if (i == 0)
            {
                minAdultAge = resultAge;
            }
            else if (i == 1)
            {
                // Restrict to adult age. Young adult is 18 according to National Institutes of Health... even if the young adult section in a library isn't that range.
                minAdultAge = Math.Min(resultAge, minAdultAge);

                // Children should be between 80 and 180 younger than the youngest adult.
                childrenAgeMax = Math.Max(minAdultAge - 80, 0);  // Allow people 10 ticks from 'adulthood' to have kids
                childrenAgeMin = Math.Max(minAdultAge - 178, 0); // Accounting gestation, which isn't simulated yet (2 ticks)
            }

            // Set default eductation output to what the game has already determined.
            resultEducation = education;

            // Apply education level randomisation if that option is selected.
            if (ModSettings.randomImmigrantEd)
            {
                if (i < 2)
                {
                    // Adults.
                    // 24% different education levels
                    int eduModifier = Singleton <SimulationManager> .instance.m_randomizer.Int32(-12, 12) / 10;

                    resultEducation += eduModifier;
                    if (resultEducation < Citizen.Education.Uneducated)
                    {
                        resultEducation = Citizen.Education.Uneducated;
                    }
                    else if (resultEducation > Citizen.Education.ThreeSchools)
                    {
                        resultEducation = Citizen.Education.ThreeSchools;
                    }
                }
                else
                {
                    // Children.
                    switch (Citizen.GetAgeGroup(resultAge))
                    {
                    case Citizen.AgeGroup.Child:
                        resultEducation = Citizen.Education.Uneducated;
                        break;

                    case Citizen.AgeGroup.Teen:
                        resultEducation = Citizen.Education.OneSchool;
                        break;

                    default:
                        // Make it that 80% graduate from high school
                        resultEducation = (Singleton <SimulationManager> .instance.m_randomizer.Int32(0, 100) < 80) ? Citizen.Education.TwoSchools : Citizen.Education.OneSchool;
                        break;
                    }
                }
            }

            // Apply education boost, if enabled, and if we're not already at the max.
            if (ModSettings.immiEduBoost && resultEducation < Citizen.Education.ThreeSchools)
            {
                ++resultEducation;
            }

            // Apply education suppression, if enabled, and if we're not already at the min.
            if (ModSettings.immiEduDrag && resultEducation > Citizen.Education.Uneducated)
            {
                --resultEducation;
            }


            // Write to immigration log if that option is selected.
            if (Logging.UseImmigrationLog)
            {
                Logging.WriteToLog(Logging.ImmigrationLogName, "Family member ", i.ToString(), " immigrating with age ", resultAge.ToString(), " (" + (int)(resultAge / 3.5), " years old) and education level ", education.ToString());
            }
        }