public static int OptimalOreForCash(double hpc, ref int searchStartpoint)
{
Ore fakeOreForBinarySearch = new Ore("", hpc, 0, 0, hpc, hpc, 0);
int maxOreIndex = oreList.BinarySearch(searchStartpoint, oreList.Count - searchStartpoint, fakeOreForBinarySearch, new MinDamageComparer());
if (maxOreIndex > 0)
{
Ore o = oreList[maxOreIndex];
if (o.MinHpcToConsider != o.MaxHpcToConsider)
{
// exactly hit a good ore at its minimum value
oreList[maxOreIndex].UpdateClicks(hpc);
return(maxOreIndex);
}
maxOreIndex--; // exactly hit a dud ore
}
else
{
// a negative return value means the ~ of the place where this value would be inserted
maxOreIndex = ~maxOreIndex - 1;
}
Ore optimalOreSoFar = fakeOreForBinarySearch;
int optimalIndex = -1;
for (int candidateIndex = maxOreIndex; candidateIndex >= 0; candidateIndex--)
{
Ore candidateOre = oreList[candidateIndex];
if (hpc < candidateOre.MaxHpcToConsider)
{
candidateOre.UpdateClicks(hpc);
if (candidateOre.ValuePerClick > optimalOreSoFar.ValuePerClick)
{
optimalOreSoFar = candidateOre;
optimalIndex = candidateIndex;
}
}
if (hpc >= candidateOre.MaxHpcOfAllAbove) // past last possible point
{
searchStartpoint = candidateIndex;
break;
}
}
return(optimalIndex);
}
public static int ComputeMostLucrativeOre(int[] upgradeState, WealthStatistics currentStatistics, out uint clicksForEachVictory, out double valueOfEachVictory)
{
double rawPickDamage = currentStatistics.CurrentP * currentStatistics.IdleActiveMultipliers() * upgradeState[(int)UpgradeID.ICAUTOPOWER & 127];
Ore fakeOreForComparingRpd = new Ore()
{
Defense = 0, Hp = rawPickDamage, MinHpcToConsider = rawPickDamage, MaxHpcToConsider = rawPickDamage
};
int lowestFeasibleOre = Ore.oreList.BinarySearch(0, currentStatistics.HighestOre + 7,
fakeOreForComparingRpd, new MinDamageComparer());
int highestFeasibleOre = Ore.oreList.BinarySearch(lowestFeasibleOre, currentStatistics.HighestOre + 7 - lowestFeasibleOre,
fakeOreForComparingRpd, new MaxDamageComparer());
if (lowestFeasibleOre < 0)
{
lowestFeasibleOre = ~lowestFeasibleOre - 1;
}
if (highestFeasibleOre < 0)
{
highestFeasibleOre = ~highestFeasibleOre;
}
int oreIndexMaxRevenue = highestFeasibleOre;
Ore oreAtMaxRevenue = Ore.oreList[oreIndexMaxRevenue];
oreAtMaxRevenue.UpdateClicks(rawPickDamage);
//double maxRevenuePerClick = oreAtMaxRevenue.ValuePerClick;
for (int i = lowestFeasibleOre; i < highestFeasibleOre; i++)
{
Ore temp = Ore.oreList[i];
temp.UpdateClicks(rawPickDamage);
if (temp.ValuePerClick > oreAtMaxRevenue.ValuePerClick)
{
oreAtMaxRevenue = temp;
oreIndexMaxRevenue = i;
}
}
if (currentStatistics.HighestOre < oreIndexMaxRevenue)
{
oreIndexMaxRevenue = currentStatistics.HighestOre;
}
clicksForEachVictory = Ore.oreList[oreIndexMaxRevenue].Clicks;
valueOfEachVictory = Ore.oreList[oreIndexMaxRevenue].Value;
return(oreIndexMaxRevenue);
}
static IList <Ore> BuildFeasibleOreList(double hpc)
{
List <Ore> localOreList = new List <Ore>();
// double bestValuePerClick = 0;
Ore fakeOreToFindOneclick = new Ore()
{
Defense = 0, Hp = hpc
};
int oneClickIndex = Ore.oreList.BinarySearch(fakeOreToFindOneclick, new OreOnehitComparer());
if (oneClickIndex < 0)
{
oneClickIndex = ~oneClickIndex - 1;
}
int bextRpc = Ore.OptimalOreForCash(hpc, oneClickIndex);
// not sure, do I need to update ores here? Or can I just skip up to oneClickIndex and then take until bextRpc?
for (int i = oneClickIndex; i <= bextRpc; i++)
{
Ore.oreList[i].UpdateClicks(hpc);
localOreList.Add(Ore.oreList[i]);
}
return(localOreList);
}
private void ARUPInternal(ClickUpgradePath soFar, double hpc, double currentGps, int af, int ap, int maxItems, List<ClickUpgradePath> retval)
{
if (maxItems == 0) return;
#if false
// gemfinder addition is handled by simulateUpgradePath
if (!soFar.UpgradeOrder.Contains(UpgradeID.ICGEMFINDER))
{
ClickUpgradePath withGemfinder = new ClickUpgradePath(soFar);
withGemfinder.UpgradeOrder.Add(UpgradeID.ICGEMFINDER);
retval.AddRange(ARUPInternal(withGemfinder, oldGemsPerSecond, af, ap, gf+1, maxItems - 1,retval));
}
#endif
var autoPowerList = Upgrade.ic(UpgradeID.ICAUTOPOWER);
var autoSpeedList = Upgrade.ic(UpgradeID.ICAUTOSPEED);
double costOfClickFaster = autoSpeedList[af].nextLevelCost;
double costOfClickPower = autoPowerList[ap].nextLevelCost;
bool clickFasterIsCheaper = costOfClickFaster < costOfClickPower;
double hpcAfterPowerUpgrade = hpc * autoPowerList[ap+1].value/autoPowerList[ap].value; // old hpc * power increment
// determine which is the optimal ore at that rawdamage level
double gpsIfYouClickPowerful = Ore.oreList[Ore.OptimalOreForCash(hpcAfterPowerUpgrade, 0)].ValuePerClick * autoSpeedList[af].value;
double clickFasterEfficiency = 1.0528/costOfClickFaster;
double clickPowerEfficiency = gpsIfYouClickPowerful/(currentGps*costOfClickPower);
bool clickFasterIsMoreEfficient = clickFasterEfficiency > clickPowerEfficiency;
ClickUpgradePath withClickFaster = new ClickUpgradePath(soFar);
withClickFaster.UpgradeOrder.Add(UpgradeID.ICAUTOSPEED);
ClickUpgradePath withClickPower = new ClickUpgradePath(soFar);
withClickPower.UpgradeOrder.Add(UpgradeID.ICAUTOPOWER);
if (clickFasterIsCheaper || clickFasterIsMoreEfficient)
{
ARUPInternal(withClickFaster,hpc,currentGps*1.0528,af+1,ap,maxItems-1,retval);
}
if (!clickFasterIsCheaper || !clickFasterIsMoreEfficient)
{
ARUPInternal(withClickPower,hpcAfterPowerUpgrade,gpsIfYouClickPowerful,af,ap+1,maxItems-1,retval);
}
}
public void Calc()
{
double bestEfficiency = 0;
ShoppingCart cartForBestEfficiency = null;
ClickUpgradePath pathForBestEfficiency = null;
int gwForBestEfficiency = -1;
var pathCollection = AllReasonableUpgradePaths();
var cartCollection = AllReasonableShoppingCarts();
var pCollection = GetPCollection(); // collection of P values to shoot for
foreach (var upgradePath in pathCollection)
{
IList<ClickUpgradePath.UpgradeSimulationResult> pathSimulationGroup = upgradePath.Simulate(initialStats);
foreach (ClickUpgradePath.UpgradeSimulationResult pathSimulation in pathSimulationGroup)
{
WealthStatistics pathResult = pathSimulation.w;
UpgradeState completedInstantUpgrades = pathSimulation.u;
double timeSpent = pathSimulation.timeSpent;
double clicksPerSecond = Upgrade.ic(UpgradeID.ICAUTOSPEED)[completedInstantUpgrades.afLevel].value;
double gemFinderOdds = Upgrade.ic(UpgradeID.ICGEMFINDER)[completedInstantUpgrades.gfLevel].value;
double autoPowerMultiplier = Upgrade.ic(UpgradeID.ICAUTOPOWER)[completedInstantUpgrades.apLevel].value;
foreach (var sc in cartCollection)
{
var costs = sc.TotalCostWithoutAndWithGemwaster();
//double timeSpentBuyingBSUpgradesOnceWeHaveEnoughMoney = (sc.NumBBP + sc.NumBF + sc.NumBS + sc.NumBX)/6.5 + (sc.NumBBP>0 ? 1 : 0) + (sc.NumBF<0 ? 1 : 0) + (sc.NumBS>0?1:0)+(sc.NumBX>0?1:0);
double efficiencyDiscount = 0.01 * (100 - completedInstantUpgrades.bfLevel - sc.NumBF);
foreach (var desiredP in pCollection)
{
int gw = 0;
foreach(var expect in sc.ChancesOfBeatingTargetAndExpectedPsIfYouDo(desiredP)) // each item corresponds to a different gemwaster
{
double costOfShoppingCart = (gw <= this.initialUpgradeState.gwLevel) ? costs.Item1 : costs.Item2;
double averageGemsForOneCraft = ShoppingCart.gwNumberOfGems[gw] * efficiencyDiscount;
double failChance = 1-expect.Item1;
// need to solve failChance^expectedNumCrafts < .2
// n ln failchance < ln .2
// n = ln .2 / ln failchance
double expectedNumCrafts = lnConfidenceLevel/Math.Log(failChance);
double expectedCraftingTime = expectedNumCrafts / 6.5;
double gemsRequired = expectedNumCrafts * averageGemsForOneCraft - pathResult.Gems; // still exact
// due to linearity of expectation
double expectedNeededOresMined = Math.Ceiling(gemsRequired / gemFinderOdds);
double hpc = pathResult.IdleActiveMultipliers()*pathResult.CurrentP*autoPowerMultiplier;
var miningList = EarnMoney.MiningPlanToEarnSpecifiedGoldAndGems(hpc, costOfShoppingCart, expectedNeededOresMined);
double timeSavingUpGoldAndGemsForCraft = miningList.Sum(x => x.Item2 * x.Item1.Clicks)*Upgrade.ic(UpgradeID.ICAUTOSPEED)[completedInstantUpgrades.afLevel].value;
double totalTime = timeSpentFollowingUpgradePath
+ timeSavingUpGoldAndGemsForCraft
//+ timeSpentBuyingBSUpgradesOnceWeHaveEnoughMoney // can buy them on-the-run
+ expectedCraftingTime;
pathResult.CurrentP = expect.Item2;
int clicksForEachVictory;
double valueOfEachVictory;
var stats = Ore.OptimalOreForCash( ); completedInstantUpgrades.instant, pathResult, out clicksForEachVictory, out valueOfEachVictory);
gw++;
}
}
}
}
}
}
internal void Simulate(WealthStatistics initialStats,
UpgradeState upgradesWithoutGemfinder,
UpgradeState upgradesWithGemfinder,
WealthStatistics wealthWithoutGemfinder,
IList<WealthStatistics> wealthWithGemfinderBoughtAfterIthUpgrade)
{
var retval = new UpgradeSimulationResult[UpgradeOrder.Count + 1];
List<WealthStatistics> currentStatistics = { new WealthStatistics(initialStats) };
UpgradeState usWithoutGemfinder = new UpgradeState(us);
UpgradeState usWithGemfinder;
bool gfMaxed = usWithoutGemfinder.gfLevel == Upgrade.ic(UpgradeID.ICGEMFINDER).Count - 1;
int itemsBoughtSoFar = 0;
double secondsPerClick = 1/Upgrade.ic(UpgradeID.ICAUTOSPEED)[usWithoutGemfinder.afLevel].value;
double gemsForEachVictoryBefore = Upgrade.ic(UpgradeID.ICGEMFINDER)[usWithoutGemfinder.gfLevel].value;
double gemsForEachVictoryAfter = gfMaxed ? 0 : Upgrade.ic(UpgradeID.ICGEMFINDER)[usWithoutGemfinder.gfLevel + 1].value;
int ore = -1;
uint clicksForEachVictory=0;
double timeForEachVictory = 0;
double valueOfEachVictory=0;
while (itemsBoughtSoFar < UpgradeOrder.Count)
{
UpgradeID pendingItem = _upgradeOrder[itemsBoughtSoFar];
int upgradeLevelOfPendingItem = usWithoutGemfinder.instant[(int)pendingItem&127];
Upgrade nextUpgrade = Upgrade.ic(pendingItem)[upgradeLevelOfPendingItem];
double nextLevelCost = nextUpgrade.nextLevelCost;
foreach (
while (currentStatistics.Any(x=>x.Gold < nextLevelCost))
{
if (ore == -1)
{
RecomputeOre(x, usWithoutGemfinder, secondsPerClick, out clicksForEachVictory, out valueOfEachVictory, out ore, out timeForEachVictory);
}
currentStatistics.ForEach(x=>
{
x.Gold += valueOfEachVictory;
x.Gems += something ? gemsForEachVictoryBefore : gemsForEachVictoryAfter;
x.dataXp += clicksForEachVictory;
x.dataAge.Add(timeForEachVictory);
timeSpent += timeForEachVictory;
if (currentStatistics.dataXp > currentStatistics.dataXpThreshold || currentStatistics.dataAge.Sum() > currentStatistics.dataAgeThreshold)
{
currentStatistics.setThresholds();
ore = -1; // or recompute now
}
if (ore == currentStatistics.HighestOre)
{
currentStatistics.HighestOre++;
ore = -1; // or recompute now
}
if (ore == -1 && currentStatistics.Gold < nextLevelCost)
{
RecomputeOre(currentStatistics, usWithoutGemfinder, secondsPerClick, out clicksForEachVictory, out valueOfEachVictory, out ore, out timeForEachVictory);
}
}
// TODO: Handle this with a dictionary or list of delegates
switch (pendingItem)
{
case UpgradeID.ICAUTOSPEED:
usWithoutGemfinder.afLevel++;
secondsPerClick = Upgrade.ic(UpgradeID.ICAUTOSPEED)[usWithoutGemfinder.afLevel].value;
timeForEachVictory = clicksForEachVictory * secondsPerClick;
break;
case UpgradeID.ICAUTOPOWER:
usWithoutGemfinder.apLevel++;
ore = Ore.ComputeMostLucrativeOre(usWithoutGemfinder.instant, currentStatistics, out clicksForEachVictory, out valueOfEachVictory);
timeForEachVictory = clicksForEachVictory * secondsPerClick;
break;
case UpgradeID.ICGEMFINDER:
usWithoutGemfinder.gfLevel++;
gemsForEachVictoryBefore = Upgrade.ic(UpgradeID.ICGEMFINDER)[usWithoutGemfinder.gfLevel].value;
break;
}
currentStatistics.Gold -= nextLevelCost;
timeSpent += 1.0; // it takes some time to click
itemsBoughtSoFar++;
}
foreach (UpgradeSimulationResult thing in retval)
{
thing.u = usWithGemfinder;
}
retval[retval.Length()-1].u = usWithoutGemfinder;
retval[retval.Length()-1].w = currentStatistics;
return Tuple.Create(currentStatistics,usWithoutGemfinder);
}
private static void RecomputeOre(WealthStatistics currentStatistics, UpgradeState currentUpgradeState, double secondsPerClick, out uint clicksForEachVictory, out double valueOfEachVictory, out int ore, out double timeForEachVictory)
{
ore = Ore.ComputeMostLucrativeOre(currentUpgradeState.instant, currentStatistics, out clicksForEachVictory, out valueOfEachVictory);
timeForEachVictory = VictorySeconds(secondsPerClick, clicksForEachVictory);
}
