public override void Calculate(SlotTypes slotType)
{
// Reading the parameters
MAMethod maMethod = (MAMethod )IndParam.ListParam[1].Index;
BasePrice basePrice = (BasePrice)IndParam.ListParam[2].Index;
int iNFastMA = (int)IndParam.NumParam[0].Value;
int iNSlowMA = (int)IndParam.NumParam[1].Value;
double dLevel = IndParam.NumParam[2].Value;
int iPrvs = IndParam.CheckParam[0].Checked ? 1 : 0;
int iFirstBar = iNSlowMA + 2;
double[] adMAFast = MovingAverage(iNFastMA, 0, maMethod, Price(basePrice));
double[] adMASlow = MovingAverage(iNSlowMA, 0, maMethod, Price(basePrice));
double[] adMAOscillator = new double[Bars];
for (int iBar = iNSlowMA; iBar < Bars; iBar++)
adMAOscillator[iBar] = adMAFast[iBar] - adMASlow[iBar];
// Saving the components
Component = new IndicatorComp[3];
Component[0] = new IndicatorComp();
Component[0].CompName = "MA Oscillator";
Component[0].DataType = IndComponentType.IndicatorValue;
Component[0].ChartType = IndChartType.Histogram;
Component[0].FirstBar = iFirstBar;
Component[0].Value = adMAOscillator;
Component[1] = new IndicatorComp();
Component[1].ChartType = IndChartType.NoChart;
Component[1].FirstBar = iFirstBar;
Component[1].Value = new double[Bars];
Component[2] = new IndicatorComp();
Component[2].ChartType = IndChartType.NoChart;
Component[2].FirstBar = iFirstBar;
Component[2].Value = new double[Bars];
// Sets the Component's type
if (slotType == SlotTypes.OpenFilter)
{
Component[1].DataType = IndComponentType.AllowOpenLong;
Component[1].CompName = "Is long entry allowed";
Component[2].DataType = IndComponentType.AllowOpenShort;
Component[2].CompName = "Is short entry allowed";
}
else if (slotType == SlotTypes.CloseFilter)
{
Component[1].DataType = IndComponentType.ForceCloseLong;
Component[1].CompName = "Close out long position";
Component[2].DataType = IndComponentType.ForceCloseShort;
Component[2].CompName = "Close out short position";
}
// Calculation of the logic
IndicatorLogic indLogic = IndicatorLogic.It_does_not_act_as_a_filter;
switch (IndParam.ListParam[0].Text)
{
case "The MA Oscillator rises":
indLogic = IndicatorLogic.The_indicator_rises;
SpecialValues = new double[1] { 0 };
break;
case "The MA Oscillator falls":
indLogic = IndicatorLogic.The_indicator_falls;
SpecialValues = new double[1] { 0 };
break;
case "The MA Oscillator is higher than the Level line":
indLogic = IndicatorLogic.The_indicator_is_higher_than_the_level_line;
SpecialValues = new double[2] { dLevel, -dLevel };
break;
case "The MA Oscillator is lower than the Level line":
indLogic = IndicatorLogic.The_indicator_is_lower_than_the_level_line;
SpecialValues = new double[2] { dLevel, -dLevel };
break;
case "The MA Oscillator crosses the Level line upward":
indLogic = IndicatorLogic.The_indicator_crosses_the_level_line_upward;
SpecialValues = new double[2] { dLevel, -dLevel };
break;
case "The MA Oscillator crosses the Level line downward":
indLogic = IndicatorLogic.The_indicator_crosses_the_level_line_downward;
SpecialValues = new double[2] { dLevel, -dLevel };
break;
case "The MA Oscillator changes its direction upward":
indLogic = IndicatorLogic.The_indicator_changes_its_direction_upward;
SpecialValues = new double[1] { 0 };
break;
case "The MA Oscillator changes its direction downward":
indLogic = IndicatorLogic.The_indicator_changes_its_direction_downward;
SpecialValues = new double[1] { 0 };
break;
default:
break;
}
OscillatorLogic(iFirstBar, iPrvs, adMAOscillator, dLevel, -dLevel, ref Component[1], ref Component[2], indLogic);
return;
}
