PerDeviceProifitDictionary GetEnabledDeviceProifitDictionary(PerDeviceSpeedDictionary speedDict, Dictionary <AlgorithmType, NiceHashSMA> NiceHashData)
{
PerDeviceProifitDictionary profitDict = new PerDeviceProifitDictionary();
// log stuff
int MAX_NAME_LEN = "daggerhashimoto".Length;
int MAX_SPEED_LEN = 15;
StringBuilder stringBuilderFull = new StringBuilder();
stringBuilderFull.AppendLine("Current device profits:");
foreach (var nameBenchKvp in speedDict)
{
var deviceUUID = nameBenchKvp.Key;
var curDevProfits = new Dictionary <AlgorithmType, double>();
StringBuilder stringBuilderDevice = new StringBuilder();
stringBuilderDevice.AppendLine(String.Format("\tProfits for {0} ({1}):", deviceUUID, ComputeDevice.GetNameForUUID(deviceUUID)));
AlgorithmType mostProfitKey = AlgorithmType.NONE;
double mostProfitAlgoVal = -1;
foreach (var algoSpeedKvp in nameBenchKvp.Value)
{
// Log stuff and calculation
string name = AlgorithmNiceHashNames.GetName(algoSpeedKvp.Key);
int namePreatyCount = MAX_NAME_LEN - name.Length;
if (namePreatyCount <= 0)
{
namePreatyCount = 1;
}
string namePreaty = name + new String(' ', namePreatyCount);
bool isEnabled = algoSpeedKvp.Value > 0;
double nhmSMADataVal = NiceHashData[algoSpeedKvp.Key].paying;
// TODO what is the constant at the end?
double algoProfit = algoSpeedKvp.Value * nhmSMADataVal * 0.000000001;
// calculate
if (isEnabled)
{
curDevProfits.Add(algoSpeedKvp.Key, algoProfit);
if (mostProfitAlgoVal < algoProfit)
{
mostProfitKey = algoSpeedKvp.Key;
mostProfitAlgoVal = algoProfit;
}
}
else
{
// if disabled make unprofitable
curDevProfits.Add(algoSpeedKvp.Key, -1000000);
algoProfit *= -1; // make bigger then 0 for logging reasons
}
// log stuff
string speedStr = algoSpeedKvp.Value.ToString("F3");
int speedStrCount = MAX_SPEED_LEN - speedStr.Length;
if (speedStrCount <= 0)
{
speedStrCount = 1;
}
string speedPreaty = new String(' ', speedStrCount) + speedStr;
stringBuilderDevice.AppendLine(String.Format("\t\t{0}\t:\tPROFIT = {1} ({2}, SPEED = {3}, NHSMA = {4})",
namePreaty, // Name
algoProfit.ToString(DOUBLE_FORMAT), // Profit
isEnabled ? "ENABLED " : "DISABLED", // ENABLED/DISABLED
speedPreaty, // Speed
nhmSMADataVal.ToString(DOUBLE_FORMAT) // NiceHashData
));
}
// add profits
profitDict.Add(deviceUUID, curDevProfits);
// log stuff
stringBuilderDevice.AppendLine(String.Format("\t\tMOST PROFITABLE (ENABLED) ALGO: {0}, PROFIT: {1}",
AlgorithmNiceHashNames.GetName(mostProfitKey),
mostProfitAlgoVal.ToString(DOUBLE_FORMAT)));
stringBuilderFull.AppendLine(stringBuilderDevice.ToString());
}
Helpers.ConsolePrint(TAG, stringBuilderFull.ToString());
return(profitDict);
}
public bool StartInitialize(IMainFormRatesComunication mainFormRatesComunication,
string miningLocation, string worker, string btcAdress)
{
_mainFormRatesComunication = mainFormRatesComunication;
_miningLocation = miningLocation;
_worker = worker;
_btcAdress = btcAdress;
if (_worker.Length > 0)
{
_workerBtcStringWorker = _btcAdress + "." + _worker;
}
else
{
_workerBtcStringWorker = _btcAdress;
}
_perDeviceSpeedDictionary = GetEnabledDeviceTypeSpeeds();
//_groupedDevicesMiners = new Dictionary<GroupedDevices, GroupMiners>();
_groupedDevicesMiners = new Dictionary <string, GroupMiners>();
_enabledDevices = new List <ComputeDevice>();
_currentAllGroupedDevices = new AllGroupedDevices();
// assume profitable
IsProfitable = true;
// this checks if there are enabled devices and enabled algorithms
bool isMiningEnabled = false;
foreach (var cdev in ComputeDevice.AllAvaliableDevices)
{
if (cdev.Enabled)
{
_enabledDevices.Add(cdev);
// check if in CPU group and add the saved CPU miners
if (cdev.DeviceGroupType == DeviceGroupType.CPU)
{
GroupedDevices gdevs = new GroupedDevices();
gdevs.Add(cdev.UUID);
cpuminer miner = _cpuMiners[cdev.Group];
CpuGroupMiner cpuGroupMiner = new CpuGroupMiner(gdevs, miner);
_groupedDevicesMiners.Add(CalcGroupedDevicesKey(gdevs), cpuGroupMiner);
}
// check if any algorithm enabled
if (!isMiningEnabled)
{
foreach (var algorithm in cdev.DeviceBenchmarkConfig.AlgorithmSettings)
{
if (!algorithm.Value.Skip)
{
isMiningEnabled = true;
break;
}
}
}
}
}
if (isMiningEnabled)
{
_preventSleepTimer.Start();
}
IsCurrentlyIdle = !isMiningEnabled;
return(isMiningEnabled);
}
/// <summary>
/// GetEnabledDeviceTypeBenchmarks calculates currently enabled ComputeDevice benchmark speeds.
/// If there are more cards of the same model it multiplies the speeds by it's count
/// </summary>
/// <returns></returns>
PerDeviceSpeedDictionary GetEnabledDeviceTypeSpeeds()
{
PerDeviceSpeedDictionary perDeviceTypeBenchmarks = new PerDeviceSpeedDictionary();
// init algorithms count 0
foreach (var curCDev in ComputeDevice.AllAvaliableDevices)
{
if (curCDev.Enabled)
{
Dictionary <AlgorithmType, double> cumulativeSpeeds = new Dictionary <AlgorithmType, double>();
var deviceConfig = curCDev.DeviceBenchmarkConfig;
foreach (var kvp in deviceConfig.AlgorithmSettings)
{
var key = kvp.Key;
cumulativeSpeeds[key] = 0;
}
perDeviceTypeBenchmarks[curCDev.UUID] = cumulativeSpeeds;
}
}
// set enabled algorithm count per device counts
foreach (var curCDev in ComputeDevice.AllAvaliableDevices)
{
if (curCDev.Enabled)
{
Dictionary <AlgorithmType, double> cumulativeSpeeds = perDeviceTypeBenchmarks[curCDev.UUID];
var deviceConfig = curCDev.DeviceBenchmarkConfig;
foreach (var kvp in deviceConfig.AlgorithmSettings)
{
var key = kvp.Key;
var algorithm = kvp.Value;
// check dagger RAM SIZE
if (algorithm.Skip ||
(algorithm.NiceHashID == AlgorithmType.DaggerHashimoto && !curCDev.IsEtherumCapale))
{
// for now set to negative value as not profitable
cumulativeSpeeds[key]--;
}
else
{
cumulativeSpeeds[key]++;
}
}
}
}
// calculate benchmarks
foreach (var curCDev in ComputeDevice.AllAvaliableDevices)
{
if (curCDev.Enabled)
{
Dictionary <AlgorithmType, double> cumulativeSpeeds = perDeviceTypeBenchmarks[curCDev.UUID];
var deviceConfig = curCDev.DeviceBenchmarkConfig;
foreach (var kvp in deviceConfig.AlgorithmSettings)
{
var key = kvp.Key;
var algorithm = kvp.Value;
// instead of cumulative speeds get just if enabled or not count x > 0 => enabled; x < 0 => disabled
if (cumulativeSpeeds[key] > 0)
{
cumulativeSpeeds[key] = algorithm.BenchmarkSpeed;
}
else
{
cumulativeSpeeds[key] = -1 * algorithm.BenchmarkSpeed;
}
}
}
}
return(perDeviceTypeBenchmarks);
}
public bool StartInitialize(IMainFormRatesComunication mainFormRatesComunication,
string miningLocation, string worker, string btcAdress)
{
_mainFormRatesComunication = mainFormRatesComunication;
_miningLocation = miningLocation;
_worker = worker;
_btcAdress = btcAdress;
if (_worker.Length > 0)
{
_workerBtcStringWorker = _btcAdress + "." + _worker;
}
else
{
_workerBtcStringWorker = _btcAdress;
}
_perDeviceSpeedDictionary = GetEnabledDeviceTypeSpeeds();
//_groupedDevicesMiners = new Dictionary<GroupedDevices, GroupMiners>();
_groupedDevicesMiners = new Dictionary <string, GroupMiners>();
_enabledDevices = new List <ComputeDevice>();
_currentAllGroupedDevices = new AllGroupedDevices();
// assume profitable
IsProfitable = true;
// assume we have internet
IsConnectedToInternet = true;
// this checks if there are enabled devices and enabled algorithms
bool isMiningEnabled = false;
foreach (var cdev in ComputeDevice.AllAvaliableDevices)
{
if (cdev.Enabled)
{
_enabledDevices.Add(cdev);
// check if any algorithm enabled
if (!isMiningEnabled)
{
foreach (var algorithm in cdev.DeviceBenchmarkConfig.AlgorithmSettings)
{
if (!algorithm.Value.Skip)
{
isMiningEnabled = true;
break;
}
}
}
}
}
if (isMiningEnabled)
{
_preventSleepTimer.Start();
_internetCheckTimer.Start();
}
IsCurrentlyIdle = !isMiningEnabled;
return(isMiningEnabled);
}
