Elliot_oscillator

ÿþ//------------------------------------------------------------------

#property copyright "© mladen, 2016, MetaQuotes Software Corp."

#property link      "www.forex-tsd.com, www.mql5.com"

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#property indicator_separate_window

#property indicator_buffers 8

#property indicator_plots   5



#property indicator_label1  "Elliot oscillator OB/OS zone"

#property indicator_type1   DRAW_FILLING

#property indicator_color1  C'209,243,209',C'255,230,183'

#property indicator_label2  "Elliot oscillator up level"

#property indicator_type2   DRAW_LINE

#property indicator_color2  clrLimeGreen

#property indicator_style2  STYLE_DOT

#property indicator_label3  "Elliot oscillator middle level"

#property indicator_type3   DRAW_LINE

#property indicator_color3  clrSilver

#property indicator_style3  STYLE_DOT

#property indicator_label4  "Elliot oscillator down level"

#property indicator_type4   DRAW_LINE

#property indicator_color4  clrOrange

#property indicator_style4  STYLE_DOT

#property indicator_label5  "Elliot oscillator"

#property indicator_type5   DRAW_COLOR_LINE

#property indicator_color5  clrSilver,clrLimeGreen,clrOrange

#property indicator_width5  2

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enum enPrices

{

   pr_close,      // Close

   pr_open,       // Open

   pr_high,       // High

   pr_low,        // Low

   pr_median,     // Median

   pr_typical,    // Typical

   pr_weighted,   // Weighted

   pr_average,    // Average (high+low+open+close)/4

   pr_medianb,    // Average median body (open+close)/2

   pr_tbiased,    // Trend biased price

   pr_tbiased2,   // Trend biased (extreme) price

   pr_haclose,    // Heiken ashi close

   pr_haopen ,    // Heiken ashi open

   pr_hahigh,     // Heiken ashi high

   pr_halow,      // Heiken ashi low

   pr_hamedian,   // Heiken ashi median

   pr_hatypical,  // Heiken ashi typical

   pr_haweighted, // Heiken ashi weighted

   pr_haaverage,  // Heiken ashi average

   pr_hamedianb,  // Heiken ashi median body

   pr_hatbiased,  // Heiken ashi trend biased price

   pr_hatbiased2  // Heiken ashi trend biased (extreme) price

};

enum enMaTypes

{

   ma_sma,    // Simple moving average

   ma_ema,    // Exponential moving average

   ma_smma,   // Smoothed MA

   ma_lwma    // Linear weighted MA

};

enum enColorOn

{

   cc_onSlope,  // Change color on slope change

   cc_onLevel,  // Change color on outer levels cross

   cc_onMiddle  // Change color on middle level cross

};



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input ENUM_TIMEFRAMES TimeFrame       = PERIOD_CURRENT; // Time frame

input int             FastPeriod      = 5;              // Fast period

input int             SlowPeriod      = 34;             // Slow period

input enMaTypes       MaMethod        = ma_sma;         // Average method

input enPrices        Price           = pr_median;      // Price

input enColorOn       ColorOn         = cc_onLevel;     // Color change 

input bool            AlertsOn        = false;          // Turn alerts on?

input bool            AlertsOnCurrent = true;           // Alert on current bar?

input bool            AlertsMessage   = true;           // Display messageas on alerts?

input bool            AlertsSound     = false;          // Play sound on alerts?

input bool            AlertsEmail     = false;          // Send email on alerts?

input bool            AlertsNotify    = false;          // Send push notification on alerts?

input bool            Interpolate     = true;           // Interpolate mtf data ?



double val[],valc[],fill1[],fill2[],levelUp[],levelMi[],levelDn[],count[];

int     _mtfHandle = INVALID_HANDLE; ENUM_TIMEFRAMES timeFrame;

#define _mtfCall iCustom(_Symbol,timeFrame,getIndicatorName(),PERIOD_CURRENT,FastPeriod,SlowPeriod,MaMethod,Price,ColorOn,AlertsOn,AlertsOnCurrent,AlertsMessage,AlertsSound,AlertsEmail,AlertsNotify)



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int OnInit()

{

   SetIndexBuffer(0,fill1  ,INDICATOR_DATA);

   SetIndexBuffer(1,fill2  ,INDICATOR_DATA);

   SetIndexBuffer(2,levelUp,INDICATOR_DATA);

   SetIndexBuffer(3,levelMi,INDICATOR_DATA);

   SetIndexBuffer(4,levelDn,INDICATOR_DATA);

   SetIndexBuffer(5,val    ,INDICATOR_DATA);

   SetIndexBuffer(6,valc   ,INDICATOR_COLOR_INDEX);

   SetIndexBuffer(7,count  ,INDICATOR_CALCULATIONS);

      for (int i=0; i<4; i++) PlotIndexSetInteger(i,PLOT_SHOW_DATA,false);

         timeFrame = MathMax(_Period,TimeFrame);

   IndicatorSetString(INDICATOR_SHORTNAME,timeFrameToString(timeFrame)+" Elliot oscillator ("+(string)FastPeriod+","+(string)SlowPeriod+")");

   return(0);

}



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int OnCalculate(const int rates_total,

                const int prev_calculated,

                const datetime& time[],

                const double& open[],

                const double& high[],

                const double& low[],

                const double& close[],

                const long& tick_volume[],

                const long& volume[],

                const int& spread[])

{

   if (Bars(_Symbol,_Period)<rates_total) return(-1);

   

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      if (timeFrame!=_Period)

      {

         double result[]; datetime currTime[],nextTime[]; 

            if (!timeFrameCheck(timeFrame,time))         return(0);

            if (_mtfHandle==INVALID_HANDLE) _mtfHandle = _mtfCall;

            if (_mtfHandle==INVALID_HANDLE)              return(0);

            if (CopyBuffer(_mtfHandle,7,0,1,result)==-1) return(0); 

      

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                #define _mtfRatio PeriodSeconds(timeFrame)/PeriodSeconds(_Period)

                int k,n,i = MathMin(MathMax(prev_calculated-1,0),MathMax(rates_total-(int)result[0]*_mtfRatio-1,0));

                for (; i<rates_total && !_StopFlag; i++ )

                {

                  #define _mtfCopy(_buff,_buffNo) if (CopyBuffer(_mtfHandle,_buffNo,time[i],1,result)==-1) break; _buff[i] = result[0]

                          _mtfCopy(fill1  ,0);

                          _mtfCopy(fill2  ,1);

                          _mtfCopy(levelUp,2);

                          _mtfCopy(levelMi,3);

                          _mtfCopy(levelDn,4);

                          _mtfCopy(val    ,5);

                          _mtfCopy(valc   ,6);

                   

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                          #define _mtfInterpolate(_buff) _buff[i-k] = _buff[i]+(_buff[i-n]-_buff[i])*k/n

                          if (!Interpolate) continue;  CopyTime(_Symbol,timeFrame,time[i  ],1,currTime); 

                              if (i<(rates_total-1)) { CopyTime(_Symbol,timeFrame,time[i+1],1,nextTime); if (currTime[0]==nextTime[0]) continue; }

                              for(n=1; (i-n)> 0 && time[i-n] >= currTime[0]; n++) continue;	

                              for(k=1; (i-k)>=0 && k<n; k++)

                              {

                                  _mtfInterpolate(fill1);

                                  _mtfInterpolate(fill2);

                                  _mtfInterpolate(levelUp);

                                  _mtfInterpolate(levelMi);

                                  _mtfInterpolate(levelDn);

                                  _mtfInterpolate(val);

                              }                                 

                }

                return(i);

      }

         

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   int levelsPeriod = (int)(SlowPeriod+MathCeil(FastPeriod/2.0));

   int i=(int)MathMax(prev_calculated-1,0); for (; i<rates_total && !_StopFlag; i++)

   {

      double price = getPrice(Price,open,close,high,low,i,rates_total);

            val[i]     = iCustomMa(MaMethod,price,FastPeriod,i,rates_total,0)-iCustomMa(MaMethod,price,SlowPeriod,i,rates_total,1);

            levelUp[i] = (val[i]>0) ? iEma(val[i],levelsPeriod,i,rates_total,2) : (i>0) ? iEma(levelUp[i-1],0,i,rates_total,2) : iEma(0,0,i,rates_total,2);

            levelDn[i] = (val[i]<0) ? iEma(val[i],levelsPeriod,i,rates_total,3) : (i>0) ? iEma(levelDn[i-1],0,i,rates_total,3) : iEma(0,0,i,rates_total,3);

            levelMi[i] = (levelUp[i]+levelDn[i])*0.5;

            switch(ColorOn)

            {

               case cc_onLevel:  valc[i] = (val[i]>levelUp[i])  ? 1 : (val[i]<levelDn[i])  ? 2 : 0; break;

               case cc_onMiddle: valc[i] = (val[i]>levelMi[i])  ? 1 : (val[i]<levelMi[i])  ? 2 : 0; break;

               default :         valc[i] = (i>0) ? (val[i]>val[i-1]) ? 1 : (val[i]<val[i-1]) ? 2 : 0 : 0;

            }                  

            fill1[i] = val[i];

            fill2[i] = (val[i]>levelUp[i]) ? levelUp[i] : (val[i]<levelDn[i]) ? levelDn[i] : val[i];

   }

   count[rates_total-1] = MathMax(rates_total-prev_calculated+1,1);

   manageAlerts(time,valc,rates_total);

   return(rates_total);

}





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#define priceInstances 1

double workHa[][priceInstances*4];

double getPrice(int tprice, const double& open[], const double& close[], const double& high[], const double& low[], int i,int _bars, int instanceNo=0)

{

  if (tprice>=pr_haclose)

   {

      if (ArrayRange(workHa,0)!= _bars) ArrayResize(workHa,_bars); instanceNo*=4;

         

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         double haOpen;

         if (i>0)

                haOpen  = (workHa[i-1][instanceNo+2] + workHa[i-1][instanceNo+3])/2.0;

         else   haOpen  = (open[i]+close[i])/2;

         double haClose = (open[i] + high[i] + low[i] + close[i]) / 4.0;

         double haHigh  = MathMax(high[i], MathMax(haOpen,haClose));

         double haLow   = MathMin(low[i] , MathMin(haOpen,haClose));



         if(haOpen  <haClose) { workHa[i][instanceNo+0] = haLow;  workHa[i][instanceNo+1] = haHigh; } 

         else                 { workHa[i][instanceNo+0] = haHigh; workHa[i][instanceNo+1] = haLow;  } 

                                workHa[i][instanceNo+2] = haOpen;

                                workHa[i][instanceNo+3] = haClose;

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         switch (tprice)

         {

            case pr_haclose:     return(haClose);

            case pr_haopen:      return(haOpen);

            case pr_hahigh:      return(haHigh);

            case pr_halow:       return(haLow);

            case pr_hamedian:    return((haHigh+haLow)/2.0);

            case pr_hamedianb:   return((haOpen+haClose)/2.0);

            case pr_hatypical:   return((haHigh+haLow+haClose)/3.0);

            case pr_haweighted:  return((haHigh+haLow+haClose+haClose)/4.0);

            case pr_haaverage:   return((haHigh+haLow+haClose+haOpen)/4.0);

            case pr_hatbiased:

               if (haClose>haOpen)

                     return((haHigh+haClose)/2.0);

               else  return((haLow+haClose)/2.0);        

            case pr_hatbiased2:

               if (haClose>haOpen)  return(haHigh);

               if (haClose<haOpen)  return(haLow);

                                    return(haClose);        

         }

   }

   

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   switch (tprice)

   {

      case pr_close:     return(close[i]);

      case pr_open:      return(open[i]);

      case pr_high:      return(high[i]);

      case pr_low:       return(low[i]);

      case pr_median:    return((high[i]+low[i])/2.0);

      case pr_medianb:   return((open[i]+close[i])/2.0);

      case pr_typical:   return((high[i]+low[i]+close[i])/3.0);

      case pr_weighted:  return((high[i]+low[i]+close[i]+close[i])/4.0);

      case pr_average:   return((high[i]+low[i]+close[i]+open[i])/4.0);

      case pr_tbiased:   

               if (close[i]>open[i])

                     return((high[i]+close[i])/2.0);

               else  return((low[i]+close[i])/2.0);        

      case pr_tbiased2:   

               if (close[i]>open[i]) return(high[i]);

               if (close[i]<open[i]) return(low[i]);

                                     return(close[i]);        

   }

   return(0);

}



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#define _maInstances 4

#define _maWorkBufferx1 1*_maInstances

double iCustomMa(int mode, double price, double length, int r, int bars, int instanceNo=0)

{

   switch (mode)

   {

      case ma_sma   : return(iSma(price,(int)length,r,bars,instanceNo));

      case ma_ema   : return(iEma(price,length,r,bars,instanceNo));

      case ma_smma  : return(iSmma(price,(int)length,r,bars,instanceNo));

      case ma_lwma  : return(iLwma(price,(int)length,r,bars,instanceNo));

      default       : return(price);

   }

}



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double workSma[][_maWorkBufferx1];

double iSma(double price, int period, int r, int _bars, int instanceNo=0)

{

   if (ArrayRange(workSma,0)!= _bars) ArrayResize(workSma,_bars); int k=1;



   workSma[r][instanceNo+0] = price;

   double avg = price; for(; k<period && (r-k)>=0; k++) avg += workSma[r-k][instanceNo+0];  avg /= (double)k;

   return(avg);

}



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double workEma[][_maWorkBufferx1];

double iEma(double price, double period, int r, int _bars, int instanceNo=0)

{

   if (ArrayRange(workEma,0)!= _bars) ArrayResize(workEma,_bars);



   workEma[r][instanceNo] = price;

   if (r>0 && period>1)

          workEma[r][instanceNo] = workEma[r-1][instanceNo]+(2.0/(1.0+period))*(price-workEma[r-1][instanceNo]);

   return(workEma[r][instanceNo]);

}



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double workSmma[][_maWorkBufferx1];

double iSmma(double price, double period, int r, int _bars, int instanceNo=0)

{

   if (ArrayRange(workSmma,0)!= _bars) ArrayResize(workSmma,_bars);



   workSmma[r][instanceNo] = price;

   if (r>1 && period>1)

          workSmma[r][instanceNo] = workSmma[r-1][instanceNo]+(price-workSmma[r-1][instanceNo])/period;

   return(workSmma[r][instanceNo]);

}



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double workLwma[][_maWorkBufferx1];

double iLwma(double price, double period, int r, int _bars, int instanceNo=0)

{

   if (ArrayRange(workLwma,0)!= _bars) ArrayResize(workLwma,_bars);

   

   workLwma[r][instanceNo] = price; if (period<1) return(price);

      double sumw = period;

      double sum  = period*price;



      for(int k=1; k<period && (r-k)>=0; k++)

      {

         double weight = period-k;

                sumw  += weight;

                sum   += weight*workLwma[r-k][instanceNo];  

      }             

      return(sum/sumw);

}



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void manageAlerts(const datetime& time[], double& ttrend[], int bars)

{

   if (!AlertsOn) return;

      int whichBar = bars-1; if (!AlertsOnCurrent) whichBar = bars-2; datetime time1 = time[whichBar];

      if (ttrend[whichBar] != ttrend[whichBar-1])

      {

         if (ttrend[whichBar] == 1) doAlert(time1,"up");

         if (ttrend[whichBar] == 2) doAlert(time1,"down");

      }         

}   



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void doAlert(datetime forTime, string doWhat)

{

   static string   previousAlert="nothing";

   static datetime previousTime;

   

   if (previousAlert != doWhat || previousTime != forTime) 

   {

      previousAlert  = doWhat;

      previousTime   = forTime;



      string message = timeFrameToString(_Period)+" "+_Symbol+" at "+TimeToString(TimeLocal(),TIME_SECONDS)+" Elliot oscillator state changed to "+doWhat;

         if (AlertsMessage) Alert(message);

         if (AlertsEmail)   SendMail(_Symbol+" Elliot oscillator",message);

         if (AlertsNotify)  SendNotification(message);

         if (AlertsSound)   PlaySound("alert2.wav");

   }

}



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string getIndicatorName()

{

   string path = MQL5InfoString(MQL5_PROGRAM_PATH);

   string data = TerminalInfoString(TERMINAL_DATA_PATH)+"\\MQL5\\Indicators\\";

   string name = StringSubstr(path,StringLen(data));

      return(name);

}



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int    _tfsPer[]={PERIOD_M1,PERIOD_M2,PERIOD_M3,PERIOD_M4,PERIOD_M5,PERIOD_M6,PERIOD_M10,PERIOD_M12,PERIOD_M15,PERIOD_M20,PERIOD_M30,PERIOD_H1,PERIOD_H2,PERIOD_H3,PERIOD_H4,PERIOD_H6,PERIOD_H8,PERIOD_H12,PERIOD_D1,PERIOD_W1,PERIOD_MN1};

string _tfsStr[]={"1 minute","2 minutes","3 minutes","4 minutes","5 minutes","6 minutes","10 minutes","12 minutes","15 minutes","20 minutes","30 minutes","1 hour","2 hours","3 hours","4 hours","6 hours","8 hours","12 hours","daily","weekly","monthly"};

string timeFrameToString(int period)

{

   if (period==PERIOD_CURRENT) 

       period = _Period;   

         int i; for(i=0;i<ArraySize(_tfsPer);i++) if(period==_tfsPer[i]) break;

   return(_tfsStr[i]);   

}



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bool timeFrameCheck(ENUM_TIMEFRAMES _timeFrame,const datetime& time[])

{

   static bool warned=false;

   if (time[0]<SeriesInfoInteger(_Symbol,_timeFrame,SERIES_FIRSTDATE))

   {

      datetime startTime,testTime[]; 

         if (SeriesInfoInteger(_Symbol,PERIOD_M1,SERIES_TERMINAL_FIRSTDATE,startTime))

         if (startTime>0)                       { CopyTime(_Symbol,_timeFrame,time[0],1,testTime); SeriesInfoInteger(_Symbol,_timeFrame,SERIES_FIRSTDATE,startTime); }

         if (startTime<=0 || startTime>time[0]) { Comment(MQL5InfoString(MQL5_PROGRAM_NAME)+"\nMissing data for "+timeFrameToString(_timeFrame)+" time frame\nRe-trying on next tick"); warned=true; return(false); }

   }

   if (warned) { Comment(""); warned=false; }

   return(true);

}