- Cuadrado
- Escalpa de Vitalik
Escalpa de Vitalik
El autor:
a624587332, Fecha: 2022-08-02 23:51:19
Las etiquetas:
// This source code is subject to the terms of the Mozilla Public License 2.0 at https://mozilla.org/MPL/2.0/
// © wielkieef
//@version=4
strategy("Vitalik Scalper", overlay = true, pyramiding=1,initial_capital = 10000, default_qty_type= strategy.percent_of_equity, default_qty_value = 100, calc_on_order_fills=false, slippage=0,commission_type=strategy.commission.percent,commission_value=0.03)
//SOURCE =============================================================================================================================================================================================================================================================================================================
src = input(open, title=" Source")
// Indicators Inputs ========================================================================================================================================================================================================================================================================================================
//ADX-------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
ADX_options = input("CLASSIC", title=" Adx Type", options = ["CLASSIC", "MASANAKAMURA"], group="Average Directional Index")
ADX_len = input(22, title=" Adx Lenght", type=input.integer, minval = 1, group="Average Directional Index")
th = input(13, title=" Adx Treshold", type=input.integer, minval = 0, group="Average Directional Index")
// Support and Resistance ---------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
SHOW_S_R = input(false, title="Show Support and Resistance levels", group="Support and Resistance")
left = input(7, title=" Left", group="Support and Resistance")
right = input(8, title=" Right", group="Support and Resistance")
// Volume ------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
volume_f = input(1.8, title=" Volume mult.", minval = 0, step = 0.1, group="Volume")
sma_length = input(33, title=" Volume lenght", minval = 1, group="Volume")
//SAR----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
SHOW_SAR = input(true, title="Show Parabolic SAR", group="SAR")
Sst = input (0.7, title=" Sar Start", step=0.01, minval = 0.01, group="SAR")
Sinc = input (0.2, title=" Sar Int", step=0.01, minval = 0.01, group="SAR")
Smax = input (0.38, title=" Sar Max", step=0.01, minval = 0.01, group="SAR")
// Range Filter ---------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
per_ = input(15, title=" Period", minval=1, group = "Range Filter")
mult = input(1.6, title=" mult.", minval=0.1, step = 0.1, group = "Range Filter")
//MACD----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
fast_length = input(15, title=" Fast Length", type=input.integer, group="MACD")
slow_length = input(16, title=" Slow Length", type=input.integer, group="MACD")
signal_length = input(21, title=" Signal Smoothing", type=input.integer, group="MACD")
//RSI----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
len_3 = input(50, title=" RSI Lenght", group = "Relative Strenght Indeks")
src_3 = input(hlc3, title=" RSI Source", group = "Relative Strenght Indeks")
//BOLINGER BANDS ----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
SHOW_BB = input(false, title="Show Bollinger Bands", group="Bolinger Bands")
tf2 = input("", title=" Timeframe 2", type = input.resolution, group="Bolinger Bands")
src2 = input(high, title=" Source 2", type = input.source, group="Bolinger Bands")
//RMI ----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
RMI_len = input(15, title=" Rmi Lenght", type=input.integer, minval = 1, group="Relative Momentum Index")
mom = input(24, title=" Rmi Momentum", type=input.integer, minval = 1, group="Relative Momentum Index")
RMI_os = input(31, title=" Rmi overbought", type=input.integer, minval = 0, group="Relative Momentum Index")
RMI_ob = input(63, title=" Rmi overbought", type=input.integer, minval = 0, group="Relative Momentum Index")
//Scalpng ----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
HiLoLen = input(6, title=" Scalping Lenght", minval=2, group="Scalping")
fastEMAlength = input(10, title=" Fast EMA lenght", minval=2, group="Scalping")
mediumEMAlength = input(120, title=" Medium EMA lenght", minval=2, group="Scalping")
slowEMAlength = input(500, title=" Slow EMA lenght", minval=2, group="Scalping")
filterBW = input(false, title=" Filter")
Lookback = input(7, title=" Pullback Lookback")
UseHAcandles = input(true, title=" Use H.A Calculations")
// ATR -------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
prd = input(2, title=" PP period", group="Average True Range")
Factor = input(4, title=" ATR Factor", group="Average True Range")
Pd = input(1, title=" ATR Period", group="Average True Range")
//TP PLOTSHAPE -----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
tp_long0 = input(0.9, title=" % TP Long", type = input.float, minval = 0, step = 0.1, group="Target Point")
tp_short0 = input(0.9, title=" % TP Short", type = input.float, minval = 0, step = 0.1, group="Target Point")
// SL PLOTSHAPE ---------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
sl0 = input(3.5, title=" % Stop loss", type = input.float, minval = 0, step = 0.1, group="Stop Loss")
//INDICATORS =======================================================================================================================================================================================================================================================================================================
//ADX-------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
calcADX(_len) =>
up = change(high)
down = -change(low)
plusDM = na(up) ? na : (up > down and up > 0 ? up : 0)
minusDM = na(down) ? na : (down > up and down > 0 ? down : 0)
truerange = rma(tr, _len)
_plus = fixnan(100 * rma(plusDM, _len) / truerange)
_minus = fixnan(100 * rma(minusDM, _len) / truerange)
sum = _plus + _minus
_adx = 100 * rma(abs(_plus - _minus) / (sum == 0 ? 1 : sum), _len)
[_plus,_minus,_adx]
calcADX_Masanakamura(_len) =>
SmoothedTrueRange = 0.0
SmoothedDirectionalMovementPlus = 0.0
SmoothedDirectionalMovementMinus = 0.0
TrueRange = max(max(high - low, abs(high - nz(close[1]))), abs(low - nz(close[1])))
DirectionalMovementPlus = high - nz(high[1]) > nz(low[1]) - low ? max(high - nz(high[1]), 0) : 0
DirectionalMovementMinus = nz(low[1]) - low > high - nz(high[1]) ? max(nz(low[1]) - low, 0) : 0
SmoothedTrueRange := nz(SmoothedTrueRange[1]) - (nz(SmoothedTrueRange[1]) /_len) + TrueRange
SmoothedDirectionalMovementPlus := nz(SmoothedDirectionalMovementPlus[1]) - (nz(SmoothedDirectionalMovementPlus[1]) / _len) + DirectionalMovementPlus
SmoothedDirectionalMovementMinus := nz(SmoothedDirectionalMovementMinus[1]) - (nz(SmoothedDirectionalMovementMinus[1]) / _len) + DirectionalMovementMinus
DIP = SmoothedDirectionalMovementPlus / SmoothedTrueRange * 100
DIM = SmoothedDirectionalMovementMinus / SmoothedTrueRange * 100
DX = abs(DIP-DIM) / (DIP+DIM)*100
adx = sma(DX, _len)
[DIP,DIM,adx]
[DIPlusC,DIMinusC,ADXC] = calcADX(ADX_len)
[DIPlusM,DIMinusM,ADXM] = calcADX_Masanakamura(ADX_len)
DIPlus = ADX_options == "CLASSIC" ? DIPlusC : DIPlusM
DIMinus = ADX_options == "CLASSIC" ? DIMinusC : DIMinusM
ADX = ADX_options == "CLASSIC" ? ADXC : ADXM
L_adx = DIPlus > DIMinus and ADX > th
S_adx = DIPlus < DIMinus and ADX > th
//SAR------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
SAR = sar(Sst, Sinc, Smax)
L_sar = (SAR < close)
S_sar = (SAR > close)
// Support and Resistance ---------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
hih = pivothigh(high, left, right)
lol = pivotlow (low , left, right)
top = valuewhen(hih, high[right], 0)
bot = valuewhen(lol, low [right], 0)
RS_Long_condt = close > top
RS_Short_condt = close < bot
L_cross = crossover(close, top)
S_cross = crossunder(close,bot)
// Volume -------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
Volume_condt = volume > sma(volume,sma_length)*volume_f
// Range Filter ----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
var bool L_RF = na, var bool S_RF = na
Range_filter(_src, _per_, _mult)=>
var float _upward = 0.0
var float _downward = 0.0
wper = (_per_*2) - 1
avrng = ema(abs(_src - _src[1]), _per_)
_smoothrng = ema(avrng, wper)*_mult
_filt = _src
_filt := _src > nz(_filt[1]) ? ((_src-_smoothrng) < nz(_filt[1]) ? nz(_filt[1]) : (_src-_smoothrng)) : ((_src+_smoothrng) > nz(_filt[1]) ? nz(_filt[1]) : (_src+_smoothrng))
_upward := _filt > _filt[1] ? nz(_upward[1]) + 1 : _filt < _filt[1] ? 0 : nz(_upward[1])
_downward := _filt < _filt[1] ? nz(_downward[1]) + 1 : _filt > _filt[1] ? 0 : nz(_downward[1])
[_smoothrng,_filt,_upward,_downward]
[smoothrng, filt, upward, downward] = Range_filter(src, per_, mult)
hband = filt + smoothrng
lband = filt - smoothrng
L_RF := high > hband and upward > 0
S_RF := low < lband and downward > 0
//MACD-----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
fast_ma = ema(src, fast_length)
slow_ma = ema(src, slow_length)
macd = fast_ma - slow_ma
signal_ = sma(macd, signal_length)
L_macd = macd > signal_
S_macd = macd < signal_
//RSI------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
up_3 = rma(max(change(src_3), 0), len_3)
down_3 = rma(-min(change(src_3), 0), len_3)
rsi_3 = down_3 == 0 ? 100 : up_3 == 0 ? 0 : 100 - (100 / (1 + up_3 / down_3))
L_rsi = (rsi_3 < 70)
S_rsi = (rsi_3 > 30)
// BOLINGER BADNS -------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
per2 = 10
dev2 = 1.0
ma2 = security(syminfo.tickerid, tf2, sma(src2, per2))
hb2 = ma2 + security(syminfo.tickerid, tf2, stdev(src2, per2)) * dev2
lb2 = ma2 - security(syminfo.tickerid, tf2, stdev(src2, per2)) * dev2
L_BB_2 = close > hb2
S_BB_2 = close > lb2
// RMI -----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
RMI(len, m)=>
up = ema(max(close - close[m],0), len)
dn = ema(max(close[m] - close,0), len)
RMI = dn == 0 ? 0 : 100 - 100 / (1 + up / dn)
RMI
L_rmi = crossover(RMI(RMI_len, mom), RMI_os)
S_rmi = crossunder(RMI(RMI_len, mom), RMI_ob)
//Scalpng ----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
haClose = UseHAcandles ? security(heikinashi(syminfo.tickerid), timeframe.period, close) : close
haOpen = UseHAcandles ? security(heikinashi(syminfo.tickerid), timeframe.period, open) : open
haHigh = UseHAcandles ? security(heikinashi(syminfo.tickerid), timeframe.period, high) : high
haLow = UseHAcandles ? security(heikinashi(syminfo.tickerid), timeframe.period, low) : low
isRegularFractal(mode) =>
ret = mode == 1 ? high[4] < high[3] and high[3] < high[2] and high[2] > high[1] and
high[1] > high[0] : mode == -1 ?
low[4] > low[3] and low[3] > low[2] and low[2] < low[1] and low[1] < low[0] :
false
ret
isBWFractal(mode) =>
ret = mode == 1 ? high[4] < high[2] and high[3] <= high[2] and high[2] >= high[1] and
high[2] > high[0] : mode == -1 ?
low[4] > low[2] and low[3] >= low[2] and low[2] <= low[1] and low[2] < low[0] :
false
ret
fastEMA = ema(haClose, fastEMAlength)
mediumEMA = ema(haClose, mediumEMAlength)
slowEMA = ema(haClose, slowEMAlength)
pacC = ema(haClose, HiLoLen)
pacL = ema(haLow, HiLoLen)
pacU = ema(haHigh, HiLoLen)
TrendDirection = fastEMA > mediumEMA and pacL > mediumEMA ? 1 :
fastEMA < mediumEMA and pacU < mediumEMA ? -1 : 0
filteredtopf = filterBW ? isRegularFractal(1) : isBWFractal(1)
filteredbotf = filterBW ? isRegularFractal(-1) : isBWFractal(-1)
valuewhen_H0 = valuewhen(filteredtopf == true, high[2], 0)
valuewhen_H1 = valuewhen(filteredtopf == true, high[2], 1)
valuewhen_H2 = valuewhen(filteredtopf == true, high[2], 2)
higherhigh = filteredtopf == false ? false :
valuewhen_H1 < valuewhen_H0 and valuewhen_H2 < valuewhen_H0
lowerhigh = filteredtopf == false ? false :
valuewhen_H1 > valuewhen_H0 and valuewhen_H2 > valuewhen_H0
valuewhen_L0 = valuewhen(filteredbotf == true, low[2], 0)
valuewhen_L1 = valuewhen(filteredbotf == true, low[2], 1)
valuewhen_L2 = valuewhen(filteredbotf == true, low[2], 2)
higherlow = filteredbotf == false ? false :
valuewhen_L1 < valuewhen_L0 and valuewhen_L2 < valuewhen_L0
lowerlow = filteredbotf == false ? false :
valuewhen_L1 > valuewhen_L0 and valuewhen_L2 > valuewhen_L0
TradeDirection = 0
TradeDirection := nz(TradeDirection[1])
pacExitU = haOpen < pacU and haClose > pacU and barssince(haClose<pacC)<=Lookback
pacExitL = haOpen > pacL and haClose < pacL and barssince(haClose>pacC)<=Lookback
Buy = TrendDirection == 1 and pacExitU
Sell = TrendDirection == -1 and pacExitL
TradeDirection := TradeDirection == 1 and haClose<pacC ? 0 :
TradeDirection == -1 and haClose>pacC ? 0 :
TradeDirection == 0 and Buy ? 1 :
TradeDirection == 0 and Sell ? -1 : TradeDirection
L_scalp = nz(TradeDirection[1]) == 0 and TradeDirection == 1
S_scalp = nz(TradeDirection[1]) == 0 and TradeDirection == -1
// ATR -------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
float ph = pivothigh(prd, prd)
float pl = pivotlow(prd, prd)
var float center = na
float lastpp = ph ? ph : pl ? pl : na
if lastpp
if na(center)
center := lastpp
else
center := (center * 2 + lastpp) / 3
Up = center - (Factor * atr(Pd))
Dn = center + (Factor * atr(Pd))
float TUp = na
float TDown = na
Trend = 0
TUp := close[1] > TUp[1] ? max(Up, TUp[1]) : Up
TDown := close[1] < TDown[1] ? min(Dn, TDown[1]) : Dn
Trend := close > TDown[1] ? 1: close < TUp[1]? -1: nz(Trend[1], 1)
Trailingsl = Trend == 1 ? TUp : TDown
bsignal = Trend == 1 and Trend[1] == -1
ssignal = Trend == -1 and Trend[1] == 1
L_ATR = Trend == 1
S_ATR = Trend == -1
//STRATEGY ==========================================================================================================================================================================================================================================================================================================
var bool longCond = na, var bool shortCond = na
var int CondIni_long = 0, var int CondIni_short = 0
var bool _Final_longCondition = na, var bool _Final_shortCondition = na
var float last_open_longCondition = na, var float last_open_shortCondition = na
var int last_longCondition = na, var int last_shortCondition = na
var int last_Final_longCondition = na, var int last_Final_shortCondition = na
var int nLongs = na, var int nShorts = na
L_1 = RS_Long_condt and L_adx and L_sar and L_RF and L_macd and L_rsi
S_1 = RS_Short_condt and S_adx and S_sar and S_RF and S_macd and S_rsi
L_2 = L_BB_2 and L_RF and Volume_condt and L_rsi
S_2 = S_BB_2 and S_RF and Volume_condt and S_rsi
L_3 = L_rmi and L_adx and L_sar and L_rsi
S_3 = S_rmi and S_adx and S_sar and S_rsi
L_4 = L_scalp and L_adx and L_RF and Volume_condt and L_rsi
S_4 = S_scalp and S_adx and S_RF and Volume_condt and S_rsi
L_basic_condt = L_1 or L_2 or L_3 or L_4
S_basic_condt = S_1 or S_2 or S_3 or S_4
longCond := L_basic_condt
shortCond := S_basic_condt
CondIni_long := longCond[1] ? 1 : shortCond[1] ? -1 : nz(CondIni_long[1] )
CondIni_short := longCond[1] ? 1 : shortCond[1] ? -1 : nz(CondIni_short[1] )
longCondition = (longCond[1] and nz(CondIni_long[1]) == -1 )
shortCondition = (shortCond[1] and nz(CondIni_short[1]) == 1 )
//POSITION PRICE-----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
var float sum_long = 0.0, var float sum_short = 0.0
var float Position_Price = 0.0
var bool Final_long_BB = na, var bool Final_short_BB = na
var int last_long_BB = na, var int last_short_BB = na
last_open_longCondition := longCondition or Final_long_BB[1] ? close[1] : nz(last_open_longCondition[1] )
last_open_shortCondition := shortCondition or Final_short_BB[1] ? close[1] : nz(last_open_shortCondition[1] )
last_longCondition := longCondition or Final_long_BB[1] ? time : nz(last_longCondition[1] )
last_shortCondition := shortCondition or Final_short_BB[1] ? time : nz(last_shortCondition[1] )
in_longCondition = last_longCondition > last_shortCondition
in_shortCondition = last_shortCondition > last_longCondition
last_Final_longCondition := longCondition ? time : nz(last_Final_longCondition[1] )
last_Final_shortCondition := shortCondition ? time : nz(last_Final_shortCondition[1] )
nLongs := nz(nLongs[1] )
nShorts := nz(nShorts[1] )
if longCondition or Final_long_BB
nLongs := nLongs + 1
nShorts := 0
sum_long := nz(last_open_longCondition) + nz(sum_long[1])
sum_short := 0.0
if shortCondition or Final_short_BB
nLongs := 0
nShorts := nShorts + 1
sum_short := nz(last_open_shortCondition)+ nz(sum_short[1])
sum_long := 0.0
Position_Price := nz(Position_Price[1])
Position_Price := longCondition or Final_long_BB ? sum_long/nLongs : shortCondition or Final_short_BB ? sum_short/nShorts : na
//TP---------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
var bool long_tp = na, var bool short_tp = na
var int last_long_tp = na, var int last_short_tp = na
var bool Final_Long_tp = na, var bool Final_Short_tp = na
var bool Final_Long_sl0 = na, var bool Final_Short_sl0 = na
var bool Final_Long_sl = na, var bool Final_Short_sl = na
var int last_long_sl = na, var int last_short_sl = na
tp_long = ((nLongs > 1) ? tp_long0 / nLongs : tp_long0) / 100
tp_short = ((nShorts > 1) ? tp_short0 / nShorts : tp_short0) / 100
long_tp := high > (fixnan(Position_Price) * (1 + tp_long)) and in_longCondition
short_tp := low < (fixnan(Position_Price) * (1 - tp_short)) and in_shortCondition
last_long_tp := long_tp ? time : nz(last_long_tp[1])
last_short_tp := short_tp ? time : nz(last_short_tp[1])
Final_Long_tp := (long_tp and last_longCondition > nz(last_long_tp[1]) and last_longCondition > nz(last_long_sl[1]))
Final_Short_tp := (short_tp and last_shortCondition > nz(last_short_tp[1]) and last_shortCondition > nz(last_short_sl[1]))
L_tp = iff(Final_Long_tp, fixnan(Position_Price) * (1 + tp_long) , na)
S_tp = iff(Final_Short_tp, fixnan(Position_Price) * (1 - tp_short) , na)
//TP SIGNALS--------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
tplLevel = (in_longCondition and
(last_longCondition > nz(last_long_tp[1])) and
(last_longCondition > nz(last_long_sl[1])) and not Final_Long_sl[1]) ?
(nLongs > 1) ?
(fixnan(Position_Price) * (1 + tp_long)) : (last_open_longCondition * (1 + tp_long)) : na
tpsLevel = (in_shortCondition and
(last_shortCondition > nz(last_short_tp[1])) and
(last_shortCondition > nz(last_short_sl[1])) and not Final_Short_sl[1]) ?
(nShorts > 1) ?
(fixnan(Position_Price) * (1 - tp_short)) : (last_open_shortCondition * (1 - tp_short)) : na
//SL ---------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
Risk = sl0
Percent_Capital = 100
sl = in_longCondition ? min(sl0,(((Risk) * 100) / (Percent_Capital * max(1, nLongs)))) :
in_shortCondition ? min(sl0,(((Risk) * 100) / (Percent_Capital * max(1, nShorts)))) : sl0
Normal_long_sl = ((in_longCondition and low <= ((1 - (sl / 100)) * (fixnan(Position_Price)))))
Normal_short_sl = ((in_shortCondition and high >= ((1 + (sl / 100)) * (fixnan(Position_Price)))))
last_long_sl := Normal_long_sl ? time : nz(last_long_sl[1])
last_short_sl := Normal_short_sl ? time : nz(last_short_sl[1])
Final_Long_sl := Normal_long_sl and last_longCondition > nz(last_long_sl[1]) and last_longCondition > nz(last_long_tp[1]) and not Final_Long_tp
Final_Short_sl := Normal_short_sl and last_shortCondition > nz(last_short_sl[1]) and last_shortCondition > nz(last_short_tp[1]) and not Final_Short_tp
//RE-ENTRY ON TP-HIT-----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
ATR_L_STOP = ssignal and in_longCondition
ATR_S_STOP = bsignal and in_shortCondition
if Final_Long_tp or Final_Long_sl
CondIni_long := -1
sum_long := 0.0
nLongs := na
if Final_Short_tp or Final_Short_sl
CondIni_short := 1
sum_short := 0.0
nShorts := na
// Colors ----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
ADX_COLOR = L_adx ? color.lime : S_adx ? color.red : color.orange
BAR_COLOR = L_cross ? #1b5e20 :S_cross ? color.maroon : L_adx ? color.lime : S_adx ? color.red : color.orange
barcolor (color = BAR_COLOR)
//PLOTS==============================================================================================================================================================================================================================================================================================================
h_BB = plot(SHOW_BB ? hb2 : na, title = "Upper Bollinger Band", color = #009688, linewidth = 2 )
l_BB = plot(SHOW_BB ? lb2 : na, title = "Lower Bollinger Band", color = #f06292, linewidth = 2 )
fill(h_BB, l_BB, title = "Bollinger Band Background", color = in_longCondition ? #009688 : #f06292, transp = 95 )
plot(SHOW_SAR ? SAR : na, title = "SAR", style=plot.style_circles, color=ADX_COLOR )
plot(L_tp, title = "TP_L", style = plot.style_circles, color = color.fuchsia, linewidth = 7 )
plot(S_tp, title = "TP_S", style = plot.style_circles, color = color.fuchsia, linewidth = 7 )
res = plot(SHOW_S_R ? top : na, style = plot.style_cross, offset=-left, color=top != top[1] ? na : color.green, linewidth = 1 )
sup = plot(SHOW_S_R ? bot : na, style = plot.style_cross, offset=-left, color=bot != bot[1] ? na : color.red, linewidth = 1 )
//PLOTSHAPES----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
plotshape(Final_Long_tp, title="TP Long Signal", style = shape.flag, location=location.abovebar, color=color.red, size=size.small , textcolor=color.red, transp = 0 )
plotshape(Final_Short_tp, title="TP Short Signal", style = shape.flag, location=location.belowbar, color=color.green, size=size.small , textcolor=color.green, transp = 0 )
plotshape(longCondition, title="Long", style=shape.triangleup, location=location.belowbar, color=color.blue, size=size.tiny , transp = 0 )
plotshape(shortCondition, title="Short", style=shape.triangledown, location=location.abovebar, color=color.red, size=size.tiny , transp = 0 )
//BACKTESTING inputs --------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
ACT_BT = input(true, title="Backtest", type = input.bool, group= "BACKTEST")
testStartYear = input(1997, title="start year", minval = 1997, maxval = 3000, group= "BACKTEST")
testStartMonth = input(06, title="start month", minval = 1, maxval = 12, group= "BACKTEST")
testStartDay = input(01, title="start day", minval = 1, maxval = 31, group= "BACKTEST")
testPeriodStart = timestamp(testStartYear,testStartMonth,testStartDay,0,0)
testStopYear = input(3333, title="stop year", minval=1980, maxval = 2222, group= "BACKTEST")
testStopMonth = input(12, title="stop month", minval=1, maxval=12, group= "BACKTEST")
testStopDay = input(31, title="stop day", minval=1, maxval=31, group= "BACKTEST")
testPeriodStop = timestamp(testStopYear, testStopMonth, testStopDay, 0, 0)
testPeriod = time >= testPeriodStart and time <= testPeriodStop ? true : false
// Backtest ==================================================================================================================================================================================================================================================================================================================================
if L_basic_condt
strategy.entry ("L", strategy.long , when = ACT_BT and testPeriod )
if S_basic_condt
strategy.entry ("S", strategy.short, when = ACT_BT and testPeriod )
strategy.exit("TP_L", "L", profit = (abs((last_open_longCondition * (1 + tp_long)) - last_open_longCondition) / syminfo.mintick), limit = nLongs >= 1 ? strategy.position_avg_price * (1 + tp_long) : na, loss = (abs((last_open_longCondition*(1-(sl/100)))-last_open_longCondition)/syminfo.mintick))
strategy.exit("TP_S", "S", profit = (abs((last_open_shortCondition * (1 - tp_short)) - last_open_shortCondition) / syminfo.mintick), limit = nShorts >= 1 ? strategy.position_avg_price*(1-(tp_short)) : na, loss = (abs((last_open_shortCondition*(1+(sl/100)))-last_open_shortCondition)/syminfo.mintick))
strategy.close_all(when = ATR_L_STOP or ATR_S_STOP)
// By wielkieef
Más.