Navigation:Home > Content >

Turbo_jvel.mq4

Time: 2014-10-06 | Download file:Turbo_jvel.mq4

//+------------------------------------------------------------------+
//|                                                   Turbo_JVEL.mq4 |
//|                           Copyright © 2005, TrendLaboratory Ltd. |
//|                   Modified by bluto to use Typical Price (HLC/3) |
//|            http://finance.groups.yahoo.com/group/TrendLaboratory |
//|            Thanks to Weld, Jurik Research http://weld.torguem.net|
//+------------------------------------------------------------------+
#property copyright "Copyright © 2005, TrendLaboratory Ltd."
#property link      "http://finance.groups.yahoo.com/group/TrendLaboratory"

#property indicator_separate_window
#property indicator_buffers 2
#property indicator_color1 Green
#property indicator_color2 Red
//---- input parameters
extern int       Length = 14;
extern int       Phase  = 0;
//---- buffers
double UpBuffer [];
double DnBuffer [];
double JMAValueBuffer [];
double fC0Buffer [];
double fA8Buffer [];
double fC8Buffer [];
//---- temporary buffers
double list[128], ring1[128], ring2[11], buffer[62];
//---- bool flag
bool   initFlag;
//---- integer vars
int    limitValue, startValue, loopParam, loopCriteria;
int    cycleLimit, highLimit, counterA, counterB;
//---- double vars
double cycleDelta, lowDValue, highDValue, absValue, paramA, paramB;
double phaseParam, logParam, JMAValue, series, sValue, sqrtParam, lengthDivider;
//---- temporary int variables
int   s58, s60, s40, s38, s68;
//+------------------------------------------------------------------+
//| JMA initFlagization function                                     |
//+------------------------------------------------------------------+
int init()
  {
   double   lengthParam;
//---- 3 additional buffers are used for counting.
   IndicatorBuffers(6);
//---- drawing settings
   SetIndexStyle  (0, DRAW_HISTOGRAM);
   SetIndexStyle  (1, DRAW_HISTOGRAM);
   SetIndexDrawBegin(0, 30);
   SetIndexDrawBegin(1, 30);
//---- 4 indicator buffers mapping
   SetIndexBuffer (0, UpBuffer);
   SetIndexBuffer (1, DnBuffer);
   SetIndexBuffer (2, JMAValueBuffer);
   SetIndexBuffer (3, fC0Buffer);
   SetIndexBuffer (4, fA8Buffer);
   SetIndexBuffer (5, fC8Buffer); 
//---- initialize one buffer (neccessary)   
   ArrayInitialize (ring2, 0);
   ArrayInitialize (ring1, 0); 
   ArrayInitialize (buffer, 0); 
//---- name for DataWindow and indicator subwindow label
   IndicatorShortName ("JMA Slope - Typical Price(" + Length + "," + Phase + ")");
   SetIndexLabel (0, "UpSlope");
   SetIndexLabel (1, "DownSlope");
//---- initial part
   limitValue = 63; 
   startValue = 64;
//----   
   for (int i = 0; i <= limitValue; i++) list [i] = -1000000; 
   for (i = startValue; i <= 127; i++)   list [i] = 1000000; 
//----
   initFlag  = true;
   if (Length < 1.0000000002) lengthParam = 0.0000000001;
   else lengthParam = (Length - 1) / 2.0;
//----   
   if (Phase < -100) phaseParam = 0.5;
   else if (Phase > 100) phaseParam = 2.5;
   else phaseParam = Phase / 100.0 + 1.5;
//----   
   logParam = MathLog (MathSqrt (lengthParam)) / MathLog (2.0);
//----
   if (logParam + 2.0 < 0) logParam = 0;
   else logParam = logParam + 2.0; 
//----
   sqrtParam     = MathSqrt(lengthParam) * logParam; 
   lengthParam   = lengthParam * 0.9; 
   lengthDivider = lengthParam / (lengthParam + 2.0);
//----  
   return;
}
//+------------------------------------------------------------------+
//| JMA iteration function                                           |
//+------------------------------------------------------------------+
int start()
  {

//---- get already counted bars    
   int counted_bars = IndicatorCounted();
//---- check for possible errors
   if (counted_bars < 0) return (-1);
   int limit = Bars - counted_bars - 1;
//---- main cycle
   for (int shift = limit; shift >= 0; shift--) {
   
      if ((Symbol()=="USDJPYm") || (Symbol()=="EURJPYm") || (Symbol()=="GBPJPYm") || (Symbol()=="USDJPY") || (Symbol()=="EURJPY") || (Symbol()=="GBPJPY"))
        {
         series = ((High[shift]+Low[shift]+Close[shift])/3);
        } else {
         series = ((High[shift]*100 + Low[shift]*100 + Close[shift]*100)/3);
        }
        
        
 
      if (loopParam < 61) { 
         loopParam++; 
         buffer [loopParam] = series; 
      } 
      if (loopParam > 30) {
         if (initFlag) { 
            initFlag = false;
             
            int diffFlag = 0; 
            for (int i = 1; i <= 29; i++) { 
               if (buffer [i + 1] != buffer [i]) diffFlag = 1;
            }  
            highLimit = diffFlag * 30;
             
            if (highLimit == 0) paramB = series;
            else paramB = buffer[1];
             
            paramA = paramB; 
            if (highLimit > 29) highLimit = 29; 
         } else 
            highLimit = 0;
//---- big cycle
         for (i = highLimit; i >= 0; i--) { 
			   if (i == 0) sValue = series; else sValue = buffer [31 - i]; 
	    
			   if (MathAbs (sValue - paramA) > MathAbs (sValue - paramB)) absValue = MathAbs(sValue - paramA); else absValue = MathAbs(sValue - paramB); 
			   double dValue = absValue + 0.0000000001; //1.0e-10; 
	
			   if (counterA <= 1) counterA = 127; else counterA--; 
			   if (counterB <= 1) counterB = 10;  else counterB--; 
			   if (cycleLimit < 128) cycleLimit++; 
			   cycleDelta += (dValue - ring2 [counterB]); 
			   ring2 [counterB] = dValue; 
			   if (cycleLimit > 10) highDValue = cycleDelta / 10.0; else highDValue = cycleDelta / cycleLimit; 
			   
			   if (cycleLimit > 127) { 
				   dValue = ring1 [counterA]; 
				   ring1 [counterA] = highDValue; 
				   s68 = 64; s58 = s68; 
				   while (s68 > 1) { 
					   if (list [s58] < dValue) { 
						   s68 = s68 / 2.0; 
						   s58 += s68; 
					   } else 
					   if (list [s58] <= dValue) { 
						   s68 = 1; 
					   } else { 
						   s68 = s68 / 2.0; 
						   s58 -= s68; 
					   }
               } 
            } else {
			      ring1 [counterA] = highDValue; 
			      if ((limitValue + startValue) > 127) {
				      startValue--; 
				      s58 = startValue; 
			      } else {
				      limitValue++; 
				      s58 = limitValue; 
			      }
			      if (limitValue > 96) s38 = 96; else s38 = limitValue; 
			      if (startValue < 32) s40 = 32; else s40 = startValue; 
		      }
//----		      
		      s68 = 64; 
		      s60 = s68; 
		      while (s68 > 1) {
			      if (list [s60] >= highDValue) {
				      if (list [s60 - 1] <= highDValue) {
					      s68 = 1; 
				      }
				      else {
					      s68 = s68 / 2.0; 
					      s60 -= s68; 
				      }
			      }
			      else {
				      s68 = s68 / 2.0; 
				      s60 += s68; 
			      }
			      if ((s60 == 127) && (highDValue > list[127])) s60 = 128; 
		      }
			   if (cycleLimit > 127) {
				   if (s58 >= s60) {
					   if (((s38 + 1) > s60) && ((s40 - 1) < s60)) 
						    lowDValue += highDValue; 
					   else if ((s40 > s60) && ((s40 - 1) < s58)) 
						    lowDValue += list [s40 - 1]; 
				   }
				   else if (s40 >= s60) {
					   if (((s38 + 1) < s60) && ((s38 + 1) > s58)) 
							    lowDValue += list[s38 + 1]; 
					}
				   else if ((s38 + 2) > s60) 
						   lowDValue += highDValue; 
				   else if (((s38 + 1) < s60) && ((s38 + 1) > s58)) 
						   lowDValue += list[s38 + 1]; 
			
				   if (s58 > s60) {
					   if (((s40 - 1) < s58) && ((s38 + 1) > s58)) 
						   lowDValue -= list [s58]; 
					   else if ((s38 < s58) && ((s38 + 1) > s60)) 
						   lowDValue -= list [s38]; 
				   }
				   else {
					   if (((s38 + 1) > s58) && ((s40 - 1) < s58)) 
						   lowDValue -= list [s58]; 
					   else if ((s40 > s58) && (s40 < s60)) 
						   lowDValue -= list [s40]; 
				   }
			   }
			   if (s58 <= s60) {
				   if (s58 >= s60) list[s60] = highDValue; else {
					   for (int j = s58 + 1; j <= (s60 - 1); j++) {
						   list [j - 1] = list[j]; 
					   }
					   list [s60 - 1] = highDValue; 
				   }
			   } else {
				   for (j = s58 - 1; j >= s60; j--) {
					   list [j + 1] = list [j]; 
				   }
				   list [s60] = highDValue; 
			   }
			
			   if (cycleLimit <= 127) {
				   lowDValue = 0; 
				   for (j = s40; j <= s38; j++) {
					   lowDValue += list[j]; 
				   }
			   }
//----			    
			   if ((loopCriteria + 1) > 31) loopCriteria = 31; else loopCriteria++; 
			   double JMATempValue, sqrtDivider = sqrtParam / (sqrtParam + 1.0);
			   
			   if (loopCriteria <= 30) {
				   if (sValue - paramA > 0) paramA = sValue; else paramA = sValue - (sValue - paramA) * sqrtDivider; 
				   if (sValue - paramB < 0) paramB = sValue; else paramB = sValue - (sValue - paramB) * sqrtDivider; 
				   JMATempValue = series;
				 
				   if (loopCriteria == 30) { 
				     fC0Buffer [shift] = series;
				     int intPart;
				      
				     if (MathCeil(sqrtParam) >= 1) intPart = MathCeil(sqrtParam); else intPart = 1; 
				     int leftInt = IntPortion (intPart); 
				     if (MathFloor(sqrtParam) >= 1) intPart = MathFloor(sqrtParam); else intPart = 1; 
				     int rightPart = IntPortion (intPart);
				     
				     if (leftInt == rightPart) dValue = 1.0; 
				     else 
					     dValue = (sqrtParam - rightPart) / (leftInt - rightPart);
			     
				     if (rightPart <= 29) int upShift = rightPart; else upShift = 29; 
				     if (leftInt <= 29) int dnShift = leftInt; else dnShift = 29; 
				     fA8Buffer [shift] = (series - buffer [loopParam - upShift]) * (1 - dValue) / rightPart + (series - buffer[loopParam - dnShift]) * dValue / leftInt;
               }
			   } else {
			      double powerValue, squareValue;
			      
			      dValue = lowDValue / (s38 - s40 + 1);
			      if (0.5 <= logParam - 2.0) powerValue = logParam - 2.0;
               else powerValue = 0.5;
               
				   if (logParam >= MathPow(absValue/dValue, powerValue)) dValue = MathPow (absValue/dValue, powerValue); else dValue = logParam; 
				   if (dValue < 1) dValue = 1;
				    
				   powerValue = MathPow (sqrtDivider, MathSqrt (dValue)); 
				   if (sValue - paramA > 0) paramA = sValue; else paramA = sValue - (sValue - paramA) * powerValue; 
				   if (sValue - paramB < 0) paramB = sValue; else paramB = sValue - (sValue - paramB) * powerValue; 
   		   }
         }
// ---- end of big cycle                  			   
         if (loopCriteria > 30) {
				JMATempValue = JMAValueBuffer [shift + 1];
            powerValue   = MathPow (lengthDivider, dValue);
            squareValue  = MathPow (powerValue, 2);
                         
				fC0Buffer [shift] = (1 - powerValue) * series + powerValue * fC0Buffer [shift + 1];
            fC8Buffer [shift] = (series - fC0Buffer [shift]) * (1 - lengthDivider) + lengthDivider * fC8Buffer [shift + 1];
            
            fA8Buffer [shift] = (phaseParam * fC8Buffer [shift] + fC0Buffer [shift] - JMATempValue) * 
                                 (powerValue * (-2.0) + squareValue + 1) + squareValue * fA8Buffer [shift + 1];  
            JMATempValue += fA8Buffer [shift]; 
         }
         JMAValue = JMATempValue;
      }
      if (loopParam <= 30) JMAValue = 0;
      JMAValueBuffer [shift] = JMAValue;
      double rel=JMAValueBuffer [shift]-JMAValueBuffer [shift+1];
      if(rel>=0)
      {
      UpBuffer[shift]=rel; 
      DnBuffer[shift]=0;
      }
      else
      { 
      DnBuffer[shift]=rel;
      UpBuffer[shift]=0;
      } 


//---- End of main cycle
   } 
   return;
}

//+------------------------------------------------------------------+
int IntPortion (double param) {
   if (param > 0) return (MathFloor (param));
   if (param < 0) return (MathCeil (param));
   return (0.0);
}
//+------------------------------------------------------------------+

Recommend