public void powerDraw(ORSResourceSuppliable pm, double power_draw) {
if (power_draws.ContainsKey(pm)) {
power_draw = power_draw / TimeWarp.fixedDeltaTime + power_draws[pm];
power_draws[pm] = power_draw;
}else {
power_draws.Add(pm, power_draw / TimeWarp.fixedDeltaTime);
}
}
public void powerDrawPerSecond(ORSResourceSuppliable pm, double power_draw, double draw_power_consumption)
{
PowerConsumption powerConsumption;
if (!power_consumption.TryGetValue(pm, out powerConsumption))
{
powerConsumption = new PowerConsumption();
power_consumption.Add(pm, powerConsumption);
}
powerConsumption.Power_draw += power_draw;
powerConsumption.Power_consume += draw_power_consumption;
}
public void powerDraw(ORSResourceSuppliable pm, double power_draw)
{
if (power_draws.ContainsKey(pm))
{
power_draw = power_draw / TimeWarp.fixedDeltaTime + power_draws[pm];
power_draws[pm] = power_draw;
}
else
{
power_draws.Add(pm, power_draw / TimeWarp.fixedDeltaTime);
}
}
public void powerDrawFixed(ORSResourceSuppliable pm, double power_draw, double power_cosumtion)
{
var timeWarpFixedDeltaTime = TimeWarpFixedDeltaTime;
var power_draw_per_second = power_draw / timeWarpFixedDeltaTime;
var power_cosumtion_per_second = power_cosumtion / timeWarpFixedDeltaTime;
PowerConsumption powerConsumption;
if (!power_consumption.TryGetValue(pm, out powerConsumption))
{
powerConsumption = new PowerConsumption();
power_consumption.Add(pm, powerConsumption);
}
powerConsumption.Power_draw += power_draw_per_second;
powerConsumption.Power_consume += power_cosumtion_per_second;
}
public void update()
{
stored_supply = powersupply;
stored_stable_supply = stable_supply;
stored_resource_demand = current_resource_demand;
double stored_current_demand = current_resource_demand;
double stored_current_hp_demand = high_priority_resource_demand;
double stored_current_charge_demand = charge_resource_demand;
stored_charge_demand = charge_resource_demand;
current_resource_demand = 0;
high_priority_resource_demand = 0;
charge_resource_demand = 0;
//Debug.Log ("Early:" + powersupply);
//stored power
List <PartResource> partresources = new List <PartResource>();
my_part.GetConnectedResources(PartResourceLibrary.Instance.GetDefinition(resource_name).id, PartResourceLibrary.Instance.GetDefinition(resource_name).resourceFlowMode, partresources);
double currentmegajoules = 0;
double maxmegajoules = 0;
foreach (PartResource partresource in partresources)
{
currentmegajoules += partresource.amount;
maxmegajoules += partresource.maxAmount;
}
if (maxmegajoules > 0)
{
resource_bar_ratio = currentmegajoules / maxmegajoules;
}
else
{
resource_bar_ratio = 0;
}
double missingmegajoules = maxmegajoules - currentmegajoules;
powersupply += currentmegajoules;
//Debug.Log ("Current:" + currentmegajoules);
double demand_supply_ratio = 0;
double high_priority_demand_supply_ratio = 0;
if (high_priority_resource_demand > 0)
{
high_priority_demand_supply_ratio = Math.Min((powersupply - stored_current_charge_demand) / stored_current_hp_demand, 1.0);
}
else
{
high_priority_demand_supply_ratio = 1.0;
}
if (stored_current_demand > 0)
{
demand_supply_ratio = Math.Min((powersupply - stored_current_charge_demand - stored_current_hp_demand) / stored_current_demand, 1.0);
}
else
{
demand_supply_ratio = 1.0;
}
//Debug.Log ("Late:" + powersupply);
//Prioritise supplying stock ElectricCharge resource
if (String.Equals(this.resource_name, ORSResourceManager.FNRESOURCE_MEGAJOULES) && stored_stable_supply > 0)
{
List <PartResource> partresources2 = new List <PartResource>();
my_part.GetConnectedResources(PartResourceLibrary.Instance.GetDefinition("ElectricCharge").id, PartResourceLibrary.Instance.GetDefinition("ElectricCharge").resourceFlowMode, partresources2);
double stock_electric_charge_needed = 0;
foreach (PartResource partresource in partresources2)
{
stock_electric_charge_needed += partresource.maxAmount - partresource.amount;
}
double power_supplied = Math.Min(powersupply * 1000 * TimeWarp.fixedDeltaTime, stock_electric_charge_needed);
if (stock_electric_charge_needed > 0)
{
current_resource_demand += stock_electric_charge_needed / 1000.0 / TimeWarp.fixedDeltaTime;
charge_resource_demand += stock_electric_charge_needed / 1000.0 / TimeWarp.fixedDeltaTime;
}
if (power_supplied > 0)
{
powersupply += my_part.RequestResource("ElectricCharge", -power_supplied) / 1000 / TimeWarp.fixedDeltaTime;
}
}
//sort by power draw
//var power_draw_items = from pair in power_draws orderby pair.Value ascending select pair;
List <KeyValuePair <ORSResourceSuppliable, double> > power_draw_items = power_draws.ToList();
power_draw_items.Sort(delegate(KeyValuePair <ORSResourceSuppliable, double> firstPair, KeyValuePair <ORSResourceSuppliable, double> nextPair) { return(firstPair.Value.CompareTo(nextPair.Value)); });
power_draw_list_archive = power_draw_items.ToList();
power_draw_list_archive.Reverse();
// check engines
foreach (KeyValuePair <ORSResourceSuppliable, double> power_kvp in power_draw_items)
{
ORSResourceSuppliable ms = power_kvp.Key;
if (ms.getPowerPriority() == 1)
{
double power = power_kvp.Value;
current_resource_demand += power;
high_priority_resource_demand += power;
if (flow_type == FNRESOURCE_FLOWTYPE_EVEN)
{
power = power * high_priority_demand_supply_ratio;
}
double power_supplied = Math.Max(Math.Min(powersupply, power), 0.0);
//Debug.Log (power + ", " + powersupply + "::: " + power_supplied);
powersupply -= power_supplied;
//notify of supply
ms.receiveFNResource(power_supplied, this.resource_name);
}
}
// check others
foreach (KeyValuePair <ORSResourceSuppliable, double> power_kvp in power_draw_items)
{
ORSResourceSuppliable ms = power_kvp.Key;
if (ms.getPowerPriority() == 2)
{
double power = power_kvp.Value;
current_resource_demand += power;
if (flow_type == FNRESOURCE_FLOWTYPE_EVEN)
{
power = power * demand_supply_ratio;
}
double power_supplied = Math.Max(Math.Min(powersupply, power), 0.0);
powersupply -= power_supplied;
//notify of supply
ms.receiveFNResource(power_supplied, this.resource_name);
}
}
// check radiators
foreach (KeyValuePair <ORSResourceSuppliable, double> power_kvp in power_draw_items)
{
ORSResourceSuppliable ms = power_kvp.Key;
if (ms.getPowerPriority() == 3)
{
double power = power_kvp.Value;
current_resource_demand += power;
if (flow_type == FNRESOURCE_FLOWTYPE_EVEN)
{
power = power * demand_supply_ratio;
}
double power_supplied = Math.Max(Math.Min(powersupply, power), 0.0);
powersupply -= power_supplied;
//notify of supply
ms.receiveFNResource(power_supplied, this.resource_name);
}
}
powersupply -= Math.Max(currentmegajoules, 0.0);
internl_power_extract = -powersupply * TimeWarp.fixedDeltaTime;
pluginSpecificImpl();
if (internl_power_extract > 0)
{
internl_power_extract = Math.Min(internl_power_extract, currentmegajoules);
}
else if (internl_power_extract < 0)
{
internl_power_extract = Math.Max(internl_power_extract, -missingmegajoules);
}
//my_part.RequestResource(this.resource_name, internl_power_extract);
ORSHelper.fixedRequestResource(my_part, this.resource_name, internl_power_extract);
powersupply = 0;
stable_supply = 0;
power_supplies.Clear();
power_draws.Clear();
}
public void update()
{
IsUpdatedAtLeastOnce = true;
stored_supply = currentPowerSupply;
stored_stable_supply = stable_supply;
stored_resource_demand = current_resource_demand;
stored_current_demand = current_resource_demand;
stored_current_hp_demand = high_priority_resource_demand;
stored_current_charge_demand = charge_resource_demand;
stored_charge_demand = charge_resource_demand;
stored_total_power_supplied = total_power_distributed;
current_resource_demand = 0;
high_priority_resource_demand = 0;
charge_resource_demand = 0;
total_power_distributed = 0;
double availableResourceAmount;
double maxResouceAmount;
my_part.GetConnectedResourceTotals(resourceDefinition.id, out availableResourceAmount, out maxResouceAmount);
if (maxResouceAmount > 0)
{
resource_bar_ratio = availableResourceAmount / maxResouceAmount;
}
else
{
resource_bar_ratio = 0;
}
double missingResourceAmount = maxResouceAmount - availableResourceAmount;
currentPowerSupply += availableResourceAmount;
double high_priority_demand_supply_ratio = high_priority_resource_demand > 0
? Math.Min((currentPowerSupply - stored_current_charge_demand) / stored_current_hp_demand, 1.0)
: 1.0;
double demand_supply_ratio = stored_current_demand > 0
? Math.Min((currentPowerSupply - stored_current_charge_demand - stored_current_hp_demand) / stored_current_demand, 1.0)
: 1.0;
//Prioritise supplying stock ElectricCharge resource
if (String.Equals(this.resource_name, ORSResourceManager.FNRESOURCE_MEGAJOULES) && stored_stable_supply > 0)
{
double amount;
double maxAmount;
my_part.GetConnectedResourceTotals(electricResourceDefinition.id, out amount, out maxAmount);
double stock_electric_charge_needed = maxAmount - amount;
double power_supplied = Math.Min(currentPowerSupply * 1000 * TimeWarp.fixedDeltaTime, stock_electric_charge_needed);
if (stock_electric_charge_needed > 0)
{
var deltaResourceDemand = stock_electric_charge_needed / 1000.0 / TimeWarp.fixedDeltaTime;
current_resource_demand += deltaResourceDemand;
charge_resource_demand += deltaResourceDemand;
}
if (power_supplied > 0)
{
double fixed_provided_electric_charge_in_MW = my_part.RequestResource(ORSResourceManager.STOCK_RESOURCE_ELECTRICCHARGE, -power_supplied) / 1000;
var provided_electric_charge_per_second = fixed_provided_electric_charge_in_MW / TimeWarp.fixedDeltaTime;
total_power_distributed += -provided_electric_charge_per_second;
currentPowerSupply += provided_electric_charge_per_second;
}
}
//sort by power draw
//var power_draw_items = from pair in power_draws orderby pair.Value ascending select pair;
List <KeyValuePair <ORSResourceSuppliable, double> > power_draw_items = power_draws.ToList();
power_draw_items.Sort
(
delegate(KeyValuePair <ORSResourceSuppliable, double> firstPair, KeyValuePair <ORSResourceSuppliable, double> nextPair)
{
return(firstPair.Value.CompareTo(nextPair.Value));
}
);
power_draw_list_archive = power_draw_items.ToList();
power_draw_list_archive.Reverse();
// check priority 1 parts like reactors
foreach (KeyValuePair <ORSResourceSuppliable, double> power_kvp in power_draw_items)
{
ORSResourceSuppliable resourceSuppliable = power_kvp.Key;
if (resourceSuppliable.getPowerPriority() == 1)
{
double power = power_kvp.Value;
current_resource_demand += power;
high_priority_resource_demand += power;
if (flow_type == FNRESOURCE_FLOWTYPE_EVEN)
{
power = power * high_priority_demand_supply_ratio;
}
double power_supplied = Math.Max(Math.Min(currentPowerSupply, power), 0.0);
currentPowerSupply -= power_supplied;
total_power_distributed += power_supplied;
//notify of supply
resourceSuppliable.receiveFNResource(power_supplied, this.resource_name);
}
}
// check priority 2 parts like engines
foreach (KeyValuePair <ORSResourceSuppliable, double> power_kvp in power_draw_items)
{
ORSResourceSuppliable resourceSuppliable = power_kvp.Key;
if (resourceSuppliable.getPowerPriority() == 2)
{
double power = power_kvp.Value;
current_resource_demand += power;
if (flow_type == FNRESOURCE_FLOWTYPE_EVEN)
{
power = power * demand_supply_ratio;
}
double power_supplied = Math.Max(Math.Min(currentPowerSupply, power), 0.0);
currentPowerSupply -= power_supplied;
total_power_distributed += power_supplied;
//notify of supply
resourceSuppliable.receiveFNResource(power_supplied, this.resource_name);
}
}
// check priority 3 parts
foreach (KeyValuePair <ORSResourceSuppliable, double> power_kvp in power_draw_items)
{
ORSResourceSuppliable resourceSuppliable = power_kvp.Key;
if (resourceSuppliable.getPowerPriority() == 3)
{
double power = power_kvp.Value;
current_resource_demand += power;
if (flow_type == FNRESOURCE_FLOWTYPE_EVEN)
{
power = power * demand_supply_ratio;
}
double power_supplied = Math.Max(Math.Min(currentPowerSupply, power), 0.0);
currentPowerSupply -= power_supplied;
total_power_distributed += power_supplied;
//notify of supply
resourceSuppliable.receiveFNResource(power_supplied, this.resource_name);
}
}
// substract avaialble resource amount to get delta resource change
currentPowerSupply -= Math.Max(availableResourceAmount, 0.0);
//internl_power_extract = -currentPowerSupply * TimeWarp.fixedDeltaTime + internl_power_extract_remainder;
internl_power_extract = -currentPowerSupply * TimeWarp.fixedDeltaTime;
pluginSpecificImpl();
if (internl_power_extract > 0)
{
internl_power_extract = Math.Min(internl_power_extract, availableResourceAmount);
}
else
{
internl_power_extract = Math.Max(internl_power_extract, -missingResourceAmount);
}
//ORSHelper.fixedRequestResource(my_part, this.resource_name, internl_power_extract);
var actual_stored_power = my_part.RequestResource(this.resource_name, internl_power_extract);
//calculate total input and output
var total_power_consumed = power_consumed.Sum(m => m.Value);
var total_power_max_supplied = power_max_supplies.Sum(m => m.Value);
var total_power_min_supplied = power_min_supplies.Sum(m => m.Value);
//generate wasteheat from used thermal power + thermal store
if (!CheatOptions.IgnoreMaxTemperature && total_power_max_supplied > 0 &&
(resourceDefinition.id == thermalpowerResourceDefinition.id || resourceDefinition.id == chargedpowerResourceDefinition.id))
{
// calculate Wasteheat
var min_supplied_per_second = TimeWarp.fixedDeltaTime * total_power_min_supplied;
var max_supplied_pers_second = TimeWarp.fixedDeltaTime * Math.Min(total_power_consumed, total_power_max_supplied) + Math.Max(-actual_stored_power, 0);
var wasteheatProduction = Math.Max(min_supplied_per_second, max_supplied_pers_second);
// generate Wasteheat
my_part.RequestResource(ORSResourceManager.FNRESOURCE_WASTEHEAT, -wasteheatProduction);
}
//internl_power_extract_remainder = internl_power_extract - actual_stored_power;
currentPowerSupply = 0;
stable_supply = 0;
power_max_supplies.Clear();
power_min_supplies.Clear();
power_draws.Clear();
power_consumed.Clear();
}
public void update(long counter)
{
var timeWarpFixedDeltaTime = TimeWarpFixedDeltaTime;
IsUpdatedAtLeastOnce = true;
Counter = counter;
stored_supply = currentPowerSupply;
stored_stable_supply = stable_supply;
stored_resource_demand = current_resource_demand;
stored_current_demand = current_resource_demand;
stored_current_hp_demand = high_priority_resource_demand;
stored_current_charge_demand = charge_resource_demand;
stored_charge_demand = charge_resource_demand;
stored_total_power_supplied = total_power_distributed;
current_resource_demand = 0;
high_priority_resource_demand = 0;
charge_resource_demand = 0;
total_power_distributed = 0;
double availableResourceAmount;
double maxResouceAmount;
my_part.GetConnectedResourceTotals(resourceDefinition.id, out availableResourceAmount, out maxResouceAmount);
if (maxResouceAmount > 0 && !double.IsNaN(maxResouceAmount) && !double.IsNaN(availableResourceAmount))
resource_bar_ratio = availableResourceAmount / maxResouceAmount;
else
resource_bar_ratio = 0.0001;
double missingResourceAmount = maxResouceAmount - availableResourceAmount;
currentPowerSupply += availableResourceAmount;
double high_priority_demand_supply_ratio = high_priority_resource_demand > 0
? Math.Min((currentPowerSupply - stored_current_charge_demand) / stored_current_hp_demand, 1.0)
: 1.0;
double demand_supply_ratio = stored_current_demand > 0
? Math.Min((currentPowerSupply - stored_current_charge_demand - stored_current_hp_demand) / stored_current_demand, 1.0)
: 1.0;
//Prioritise supplying stock ElectricCharge resource
if (resourceDefinition.id == megajouleResourceDefinition.id && stored_stable_supply > 0)
{
double amount;
double maxAmount;
my_part.GetConnectedResourceTotals(electricResourceDefinition.id, out amount, out maxAmount);
double stock_electric_charge_needed = maxAmount - amount;
double power_supplied = Math.Min(currentPowerSupply * 1000 * timeWarpFixedDeltaTime, stock_electric_charge_needed);
if (stock_electric_charge_needed > 0)
{
var deltaResourceDemand = stock_electric_charge_needed / 1000 / timeWarpFixedDeltaTime;
current_resource_demand += deltaResourceDemand;
charge_resource_demand += deltaResourceDemand;
}
if (power_supplied > 0)
{
double fixed_provided_electric_charge_in_MW = my_part.RequestResource(ORSResourceManager.STOCK_RESOURCE_ELECTRICCHARGE, -power_supplied) / 1000;
var provided_electric_charge_per_second = fixed_provided_electric_charge_in_MW / timeWarpFixedDeltaTime;
total_power_distributed += -provided_electric_charge_per_second;
currentPowerSupply += provided_electric_charge_per_second;
}
}
power_supply_list_archive = power_produced.OrderByDescending(m => m.Value.maximumSupply).ToList();
// store current supply and update average
power_supply_list_archive.ForEach(m =>
{
Queue<double> queue;
if (!power_produced_history.TryGetValue(m.Key, out queue))
{
queue = new Queue<double>(10);
power_produced_history.Add(m.Key, queue);
}
if (queue.Count > 10)
queue.Dequeue();
queue.Enqueue(m.Value.currentSupply);
m.Value.averageSupply = queue.Average();
});
List<KeyValuePair<ORSResourceSuppliable, PowerConsumption>> power_draw_items = power_consumption.OrderBy(m => m.Value.Power_draw).ToList();
power_draw_list_archive = power_draw_items.ToList();
power_draw_list_archive.Reverse();
// check priority 1 parts like reactors
foreach (KeyValuePair<ORSResourceSuppliable, PowerConsumption> power_kvp in power_draw_items)
{
ORSResourceSuppliable resourceSuppliable = power_kvp.Key;
if (resourceSuppliable.getPowerPriority() == 1)
{
double power = power_kvp.Value.Power_draw;
current_resource_demand += power;
high_priority_resource_demand += power;
if (flow_type == FNRESOURCE_FLOWTYPE_EVEN)
power = power * high_priority_demand_supply_ratio;
double power_supplied = Math.Max(Math.Min(currentPowerSupply, power), 0.0);
currentPowerSupply -= power_supplied;
total_power_distributed += power_supplied;
//notify of supply
resourceSuppliable.receiveFNResource(power_supplied, this.resource_name);
}
}
// check priority 2 parts like reactors
foreach (KeyValuePair<ORSResourceSuppliable, PowerConsumption> power_kvp in power_draw_items)
{
ORSResourceSuppliable resourceSuppliable = power_kvp.Key;
if (resourceSuppliable.getPowerPriority() == 2)
{
double power = power_kvp.Value.Power_draw;
current_resource_demand += power;
if (flow_type == FNRESOURCE_FLOWTYPE_EVEN)
power = power * demand_supply_ratio;
double power_supplied = Math.Max(Math.Min(currentPowerSupply, power), 0.0);
currentPowerSupply -= power_supplied;
total_power_distributed += power_supplied;
//notify of supply
resourceSuppliable.receiveFNResource(power_supplied, this.resource_name);
}
}
// check priority 3 parts like engines and nuclear reactors
foreach (KeyValuePair<ORSResourceSuppliable, PowerConsumption> power_kvp in power_draw_items)
{
ORSResourceSuppliable resourceSuppliable = power_kvp.Key;
if (resourceSuppliable.getPowerPriority() == 3)
{
double power = power_kvp.Value.Power_draw;
current_resource_demand += power;
if (flow_type == FNRESOURCE_FLOWTYPE_EVEN)
power = power * demand_supply_ratio;
double power_supplied = Math.Max(Math.Min(currentPowerSupply, power), 0.0);
currentPowerSupply -= power_supplied;
total_power_distributed += power_supplied;
//notify of supply
resourceSuppliable.receiveFNResource(power_supplied, this.resource_name);
}
}
// check priority 4 parts like antimatter reactors, engines and transmitters
foreach (KeyValuePair<ORSResourceSuppliable, PowerConsumption> power_kvp in power_draw_items)
{
ORSResourceSuppliable resourceSuppliable = power_kvp.Key;
if (resourceSuppliable.getPowerPriority() == 4)
{
double power = power_kvp.Value.Power_draw;
current_resource_demand += power;
if (flow_type == FNRESOURCE_FLOWTYPE_EVEN)
power = power * demand_supply_ratio;
double power_supplied = Math.Max(Math.Min(currentPowerSupply, power), 0.0);
currentPowerSupply -= power_supplied;
total_power_distributed += power_supplied;
//notify of supply
resourceSuppliable.receiveFNResource(power_supplied, this.resource_name);
}
}
// check priority 5 parts and higher
foreach (KeyValuePair<ORSResourceSuppliable, PowerConsumption> power_kvp in power_draw_items)
{
ORSResourceSuppliable resourceSuppliable = power_kvp.Key;
if (resourceSuppliable.getPowerPriority() >= 5)
{
double power = power_kvp.Value.Power_draw;
current_resource_demand += power;
if (flow_type == FNRESOURCE_FLOWTYPE_EVEN)
power = power * demand_supply_ratio;
double power_supplied = Math.Max(Math.Min(currentPowerSupply, power), 0.0);
currentPowerSupply -= power_supplied;
total_power_distributed += power_supplied;
//notify of supply
resourceSuppliable.receiveFNResource(power_supplied, this.resource_name);
}
}
// substract avaialble resource amount to get delta resource change
currentPowerSupply -= Math.Max(availableResourceAmount, 0.0);
internl_power_extract_fixed = -currentPowerSupply * timeWarpFixedDeltaTime;
pluginSpecificImpl();
if (internl_power_extract_fixed > 0)
internl_power_extract_fixed = Math.Min(internl_power_extract_fixed, availableResourceAmount);
else
internl_power_extract_fixed = Math.Max(internl_power_extract_fixed, -missingResourceAmount);
my_part.RequestResource(this.resource_name, internl_power_extract_fixed);
//calculate total input and output
//var total_current_supplied = power_produced.Sum(m => m.Value.currentSupply);
//var total_current_provided = power_produced.Sum(m => m.Value.currentProvided);
//var total_power_consumed = power_consumption.Sum(m => m.Value.Power_consume);
//var total_power_min_supplied = power_produced.Sum(m => m.Value.minimumSupply);
////generate wasteheat from used thermal power + thermal store
//if (!CheatOptions.IgnoreMaxTemperature && total_current_produced > 0 &&
// (resourceDefinition.id == thermalpowerResourceDefinition.id || resourceDefinition.id == chargedpowerResourceDefinition.id))
//{
// var min_supplied_fixed = TimeWarp.fixedDeltaTime * total_power_min_supplied;
// var used_or_stored_power_fixed = TimeWarp.fixedDeltaTime * Math.Min(total_power_consumed, total_current_produced) + Math.Max(-actual_stored_power, 0);
// var wasteheat_produced_fixed = Math.Max(min_supplied_fixed, used_or_stored_power_fixed);
// var effective_wasteheat_ratio = Math.Max(wasteheat_produced_fixed / (total_current_produced * TimeWarp.fixedDeltaTime), 1);
// ORSResourceManager manager = ORSResourceOvermanager.getResourceOvermanagerForResource(ORSResourceManager.FNRESOURCE_WASTEHEAT).getManagerForVessel(my_vessel);
// foreach (var supplier_key_value in power_produced)
// {
// if (supplier_key_value.Value.currentSupply > 0)
// {
// manager.powerSupplyPerSecondWithMax(supplier_key_value.Key, supplier_key_value.Value.currentSupply * effective_wasteheat_ratio, supplier_key_value.Value.maximumSupply * effective_wasteheat_ratio);
// }
// }
//}
currentPowerSupply = 0;
stable_supply = 0;
power_produced.Clear();
power_consumption.Clear();
}
