Timeframe
5m
Direction
Long Only
Stoploss
-99.8%
Trailing Stop
No
ROI
0m: 10.0%
Interface Version
3
Startup Candles
N/A
Indicators
19
freqtrade/freqtrade-strategies
Strategy 003 author@: Gerald Lonlas github@: https://github.com/freqtrade/freqtrade-strategies
# --- Do not remove these libs ---
import freqtrade.vendor.qtpylib.indicators as qtpylib
import logging
import math
import numpy as np
import talib.abstract as ta
import pandas_ta as pta
from freqtrade.persistence import Trade
from freqtrade.strategy.interface import IStrategy
from pandas import DataFrame, Series, DatetimeIndex, merge
from datetime import datetime, timedelta
from freqtrade.strategy import merge_informative_pair, CategoricalParameter, DecimalParameter, IntParameter, stoploss_from_open
from functools import reduce
from technical.indicators import RMI, zema
logger = logging.getLogger(__name__)
# --------------------------------
def ha_typical_price(bars):
res = (bars['ha_high'] + bars['ha_low'] + bars['ha_close']) / 3.0
return Series(index=bars.index, data=res)
def is_support(row_data) -> bool:
conditions = []
for row in range(len(row_data) - 1):
if row < len(row_data) / 2:
conditions.append(row_data[row] > row_data[row + 1])
else:
conditions.append(row_data[row] < row_data[row + 1])
return reduce(lambda x, y: x & y, conditions)
def is_resistance(row_data) -> bool:
conditions = []
for row in range(len(row_data) - 1):
if row < len(row_data) / 2:
conditions.append(row_data[row] < row_data[row + 1])
else:
conditions.append(row_data[row] > row_data[row + 1])
return reduce(lambda x, y: x & y, conditions)
def EWO(dataframe, ema_length=5, ema2_length=35):
df = dataframe.copy()
ema1 = ta.EMA(df, timeperiod=ema_length)
ema2 = ta.EMA(df, timeperiod=ema2_length)
emadif = (ema1 - ema2) / df['low'] * 100
return emadif
# Volume Weighted Moving Average
def vwma(dataframe: DataFrame, length: int=10):
"""Indicator: Volume Weighted Moving Average (VWMA)"""
# Calculate Result
pv = dataframe['close'] * dataframe['volume']
vwma = Series(ta.SMA(pv, timeperiod=length) / ta.SMA(dataframe['volume'], timeperiod=length))
return vwma
# Modified Elder Ray Index
def moderi(dataframe: DataFrame, len_slow_ma: int=32) -> Series:
slow_ma = Series(ta.EMA(vwma(dataframe, length=len_slow_ma), timeperiod=len_slow_ma))
return slow_ma >= slow_ma.shift(1) # we just need true & false for ERI trend
# Williams %R
def williams_r(dataframe: DataFrame, period: int=14) -> Series:
"""Williams %R, or just %R, is a technical analysis oscillator showing the current closing price in relation to the high and low
of the past N days (for a given N). It was developed by a publisher and promoter of trading materials, Larry Williams.
Its purpose is to tell whether a stock or commodity market is trading near the high or the low, or somewhere in between,
of its recent trading range.
The oscillator is on a negative scale, from −100 (lowest) up to 0 (highest).
"""
highest_high = dataframe['high'].rolling(center=False, window=period).max()
lowest_low = dataframe['low'].rolling(center=False, window=period).min()
WR = Series((highest_high - dataframe['close']) / (highest_high - lowest_low), name=f'{period} Williams %R')
return WR * -100
# VWAP bands
def VWAPB(dataframe, window_size=20, num_of_std=1):
df = dataframe.copy()
df['vwap'] = qtpylib.rolling_vwap(df, window=window_size)
rolling_std = df['vwap'].rolling(window=window_size).std()
df['vwap_low'] = df['vwap'] - rolling_std * num_of_std
df['vwap_high'] = df['vwap'] + rolling_std * num_of_std
return (df['vwap_low'], df['vwap'], df['vwap_high'])
def top_percent_change(dataframe: DataFrame, length: int) -> float:
"""
Percentage change of the current close from the range maximum Open price
:param dataframe: DataFrame The original OHLC dataframe
:param length: int The length to look back
"""
if length == 0:
return (dataframe['open'] - dataframe['close']) / dataframe['close']
else:
return (dataframe['open'].rolling(length).max() - dataframe['close']) / dataframe['close']
class BB_RTR(IStrategy):
INTERFACE_VERSION = 3
'\n BB_RPB_TSL_RNG with conditions from true_lambo and dca\n\n (1) add btc protection to conditions prone to entry high\n\n '
##########################################################################
# Hyperopt result area
# entry space
##
##
##
##
##
##
##
##
##
##
##
##
##
entry_params = {'entry_pump_1_factor': 1.096, 'entry_pump_2_factor': 1.125, 'entry_threshold': 0.003, 'entry_bb_factor': 0.999, 'entry_bb_delta': 0.025, 'entry_bb_width': 0.095, 'entry_cci': -116, 'entry_cci_length': 25, 'entry_rmi': 49, 'entry_rmi_length': 17, 'entry_srsi_fk': 32, 'entry_closedelta': 12.148, 'entry_ema_diff': 0.022, 'entry_adx': 20, 'entry_fastd': 20, 'entry_fastk': 22, 'entry_ema_cofi': 0.98, 'entry_ewo_high': 4.179, 'entry_ema_high': 0.968, 'entry_ema_low': 0.935, 'entry_ewo': -5.001, 'entry_rsi': 23, 'entry_rsi_fast': 44, 'entry_ema_high_2': 1.087, 'entry_ema_low_2': 0.97, 'entry_no_trend_cti_4': -0.597, 'entry_no_trend_factor_4': 0.024, 'entry_no_trend_r14_4': -44.062, 'entry_V_bb_width_5': 0.063, 'entry_V_cti_5': -0.086, 'entry_V_mfi_5': 38.158, 'entry_V_r14_5': -41.493, 'entry_vwap_closedelta': 26.941, 'entry_vwap_closedelta_2': 20.099, 'entry_vwap_closedelta_3': 27.654, 'entry_vwap_cti': -0.087, 'entry_vwap_cti_2': -0.748, 'entry_vwap_cti_3': -0.2, 'entry_vwap_width': 1.308, 'entry_vwap_width_2': 3.212, 'entry_vwap_width_3': 0.49, 'entry_ada_cti': -0.715, 'entry_ada_mama_diff': -0.025, 'entry_ada_mama_offset': 0.981, 'entry_ada_r_14': -61.294}
# exit space
# Disable ?
##
##
##
##
exit_params = {'pHSL': -0.998, 'pPF_1': 0.019, 'pPF_2': 0.065, 'pSL_1': 0.019, 'pSL_2': 0.062, 'exit_cti_r_cti': 0.844, 'exit_cti_r_r': -19.99, 'exit_u_e_2_cmf': -0.0, 'exit_u_e_2_ema_close_delta': 0.016, 'exit_u_e_2_rsi': 10, 'exit_deadfish_profit': -0.063, 'exit_deadfish_bb_factor': 0.954, 'exit_deadfish_bb_width': 0.043, 'exit_deadfish_volume_factor': 2.37, 'exit_cmf_div_1_cmf': 0.442, 'exit_cmf_div_1_profit': 0.02}
# ROI
minimal_roi = {'0': 0.1}
# Optimal timeframe for the strategy
timeframe = '5m'
inf_1h = '1h'
# Disabled
stoploss = -0.998
# Options
use_custom_stoploss = True
use_exit_signal = True
process_only_new_candles = True
startup_candle_count: int = 400
############################################################################
## Buy params
is_optimize_dip = False
entry_rmi = IntParameter(30, 50, default=35, optimize=is_optimize_dip)
entry_cci = IntParameter(-135, -90, default=-133, optimize=is_optimize_dip)
entry_srsi_fk = IntParameter(30, 50, default=25, optimize=is_optimize_dip)
entry_cci_length = IntParameter(25, 45, default=25, optimize=is_optimize_dip)
entry_rmi_length = IntParameter(8, 20, default=8, optimize=is_optimize_dip)
is_optimize_break = False
entry_bb_width = DecimalParameter(0.05, 0.2, default=0.15, optimize=is_optimize_break)
entry_bb_delta = DecimalParameter(0.025, 0.08, default=0.04, optimize=is_optimize_break)
is_optimize_local_dip = False
entry_ema_diff = DecimalParameter(0.022, 0.027, default=0.025, optimize=is_optimize_local_dip)
entry_bb_factor = DecimalParameter(0.99, 0.999, default=0.995, optimize=False)
entry_closedelta = DecimalParameter(12.0, 18.0, default=15.0, optimize=is_optimize_local_dip)
is_optimize_ewo = False
entry_rsi_fast = IntParameter(35, 50, default=45, optimize=False)
entry_rsi = IntParameter(15, 30, default=35, optimize=False)
entry_ewo = DecimalParameter(-6.0, 5, default=-5.585, optimize=is_optimize_ewo)
entry_ema_low = DecimalParameter(0.9, 0.99, default=0.942, optimize=is_optimize_ewo)
entry_ema_high = DecimalParameter(0.95, 1.2, default=1.084, optimize=is_optimize_ewo)
is_optimize_ewo_2 = False
entry_ema_low_2 = DecimalParameter(0.96, 0.978, default=0.96, optimize=is_optimize_ewo_2)
entry_ema_high_2 = DecimalParameter(1.05, 1.2, default=1.09, optimize=is_optimize_ewo_2)
is_optimize_cofi = False
entry_ema_cofi = DecimalParameter(0.96, 0.98, default=0.97, optimize=is_optimize_cofi)
entry_fastk = IntParameter(20, 30, default=20, optimize=is_optimize_cofi)
entry_fastd = IntParameter(20, 30, default=20, optimize=is_optimize_cofi)
entry_adx = IntParameter(20, 30, default=30, optimize=is_optimize_cofi)
entry_ewo_high = DecimalParameter(2, 12, default=3.553, optimize=is_optimize_cofi)
is_optimize_vwap = False
entry_vwap_width = DecimalParameter(0.05, 10.0, default=0.8, optimize=is_optimize_vwap)
entry_vwap_closedelta = DecimalParameter(10.0, 30.0, default=15.0, optimize=is_optimize_vwap)
entry_vwap_cti = DecimalParameter(-0.9, -0.0, default=-0.6, optimize=is_optimize_vwap)
is_optimize_vwap_2 = False
entry_vwap_width_2 = DecimalParameter(0.05, 10.0, default=0.8, optimize=is_optimize_vwap_2)
entry_vwap_closedelta_2 = DecimalParameter(10.0, 30.0, default=15.0, optimize=is_optimize_vwap_2)
entry_vwap_cti_2 = DecimalParameter(-0.9, -0.0, default=-0.6, optimize=is_optimize_vwap_2)
is_optimize_vwap_3 = False
entry_vwap_width_3 = DecimalParameter(0.05, 10.0, default=0.8, optimize=is_optimize_vwap_3)
entry_vwap_closedelta_3 = DecimalParameter(10.0, 30.0, default=15.0, optimize=is_optimize_vwap_3)
entry_vwap_cti_3 = DecimalParameter(-0.9, -0.0, default=-0.6, optimize=is_optimize_vwap_3)
is_optimize_no_trend_4 = False
entry_no_trend_factor_4 = DecimalParameter(0.01, 0.05, default=0.03, optimize=is_optimize_no_trend_4)
entry_no_trend_cti_4 = DecimalParameter(-0.9, -0.0, default=-0.6, optimize=is_optimize_no_trend_4)
entry_no_trend_r14_4 = DecimalParameter(-100, -44, default=-80, optimize=is_optimize_no_trend_4)
is_optimize_V_5 = False
entry_V_bb_width_5 = DecimalParameter(0.01, 0.1, default=0.01, optimize=is_optimize_V_5)
entry_V_cti_5 = DecimalParameter(-0.95, -0.0, default=-0.6, optimize=is_optimize_V_5)
entry_V_r14_5 = DecimalParameter(-100, 0, default=-60, optimize=is_optimize_V_5)
entry_V_mfi_5 = DecimalParameter(10, 40, default=30, optimize=is_optimize_V_5)
is_optimize_ada = True
entry_ada_mama_offset = DecimalParameter(0.9, 1.2, default=1, optimize=is_optimize_ada)
entry_ada_r_14 = DecimalParameter(-100, -44, default=-82, optimize=is_optimize_ada)
entry_ada_mama_diff = DecimalParameter(-0.05, -0.01, default=-0.019, optimize=is_optimize_ada)
entry_ada_cti = DecimalParameter(-1, -0.4, default=-0.82, optimize=is_optimize_ada)
is_optimize_gumbo = False
entry_gumbo_ema = DecimalParameter(0.9, 1.2, default=0.97, optimize=is_optimize_gumbo)
entry_gumbo_ewo_low = DecimalParameter(-12.0, 5, default=-5.585, optimize=is_optimize_gumbo)
entry_gumbo_cti = DecimalParameter(-0.9, -0.0, default=-0.5, optimize=is_optimize_gumbo)
entry_gumbo_r14 = DecimalParameter(-100, -44, default=-60, optimize=is_optimize_gumbo)
is_optimize_gumbo_protection = False
entry_gumbo_tpct_0 = DecimalParameter(0.0, 0.25, default=0.131, decimals=2, optimize=is_optimize_gumbo_protection)
entry_gumbo_tpct_3 = DecimalParameter(0.0, 0.25, default=0.131, decimals=2, optimize=is_optimize_gumbo_protection)
entry_gumbo_tpct_9 = DecimalParameter(0.0, 0.25, default=0.131, decimals=2, optimize=is_optimize_gumbo_protection)
# Buy params toggle
entry_is_dip_enabled = CategoricalParameter([True, False], default=True, space='entry', optimize=False, load=True)
entry_is_break_enabled = CategoricalParameter([True, False], default=True, space='entry', optimize=False, load=True)
is_optimize_pump_1 = False
entry_pump_1_factor = DecimalParameter(1.0, 1.25, default=1.1, optimize=is_optimize_pump_1)
is_optimize_pump_2 = False
entry_pump_2_factor = DecimalParameter(1.0, 1.2, default=1.1, optimize=is_optimize_pump_2)
## Sell params
is_optimize_exit_u_e_2 = False
exit_u_e_2_cmf = DecimalParameter(-0.4, 0.0, default=0.0, optimize=is_optimize_exit_u_e_2)
exit_u_e_2_ema_close_delta = DecimalParameter(0.001, 0.027, default=0.024, optimize=is_optimize_exit_u_e_2)
exit_u_e_2_rsi = IntParameter(10, 30, default=24, optimize=is_optimize_exit_u_e_2)
is_optimize_deadfish = False
exit_deadfish_bb_width = DecimalParameter(0.01, 0.025, default=0.05, optimize=is_optimize_deadfish)
exit_deadfish_profit = DecimalParameter(-0.1, -0.05, default=-0.05, optimize=is_optimize_deadfish)
exit_deadfish_bb_factor = DecimalParameter(0.9, 1.2, default=1.0, optimize=is_optimize_deadfish)
exit_deadfish_volume_factor = DecimalParameter(1.5, 3, default=1.5, optimize=is_optimize_deadfish)
is_optimize_cti_r = False
exit_cti_r_cti = DecimalParameter(0.55, 1, default=0.5, optimize=is_optimize_cti_r)
exit_cti_r_r = DecimalParameter(-15, 0, default=-20, optimize=is_optimize_cti_r)
is_optimize_cmf_div = False
exit_cmf_div_1_profit = DecimalParameter(0.005, 0.02, default=0.005, optimize=is_optimize_cmf_div)
exit_cmf_div_1_cmf = DecimalParameter(0.0, 0.5, default=0.0, optimize=is_optimize_cmf_div)
exit_cmf_div_2_profit = DecimalParameter(0.005, 0.02, default=0.005, optimize=is_optimize_cmf_div)
exit_cmf_div_2_cmf = DecimalParameter(0.0, 0.5, default=0.0, optimize=is_optimize_cmf_div)
## Trailing params
is_optimize_trailing = True
pHSL = DecimalParameter(-0.2, -0.04, default=-0.08, decimals=3, space='exit', load=True, optimize=False)
pPF_1 = DecimalParameter(0.008, 0.03, default=0.016, decimals=3, space='exit', load=True, optimize=False)
pSL_1 = DecimalParameter(0.008, 0.03, default=0.011, decimals=3, space='exit', load=True, optimize=is_optimize_trailing)
# profit threshold 2, SL_2 is used
pPF_2 = DecimalParameter(0.05, 0.2, default=0.08, decimals=3, space='exit', load=True, optimize=is_optimize_trailing)
pSL_2 = DecimalParameter(0.03, 0.2, default=0.04, decimals=3, space='exit', load=True, optimize=is_optimize_trailing)
############################################################################
def informative_pairs(self):
pairs = self.dp.current_whitelist()
informative_pairs = [(pair, '1h') for pair in pairs]
informative_pairs += [('BTC/USDT', '5m')]
return informative_pairs
############################################################################
## Custom Trailing stoploss ( credit to Perkmeister for this custom stoploss to help the strategy ride a green candle )
def custom_stoploss(self, pair: str, trade: 'Trade', current_time: datetime, current_rate: float, current_profit: float, **kwargs) -> float:
# hard stoploss profit
HSL = self.pHSL.value
PF_1 = self.pPF_1.value
SL_1 = self.pSL_1.value
PF_2 = self.pPF_2.value
SL_2 = self.pSL_2.value
# For profits between PF_1 and PF_2 the stoploss (sl_profit) used is linearly interpolated
# between the values of SL_1 and SL_2. For all profits above PL_2 the sl_profit value
# rises linearly with current profit, for profits below PF_1 the hard stoploss profit is used.
if current_profit > PF_2:
sl_profit = SL_2 + (current_profit - PF_2)
elif current_profit > PF_1:
sl_profit = SL_1 + (current_profit - PF_1) * (SL_2 - SL_1) / (PF_2 - PF_1)
else:
sl_profit = HSL
# Only for hyperopt invalid return
if sl_profit >= current_profit:
return -0.99
return stoploss_from_open(sl_profit, current_profit)
def confirm_trade_entry(self, pair: str, order_type: str, amount: float, rate: float, time_in_force: str, **kwargs) -> bool:
dataframe, _ = self.dp.get_analyzed_dataframe(pair, self.timeframe)
max_slip = 0.983
if len(dataframe) < 1:
return False
dataframe = dataframe.iloc[-1].squeeze()
if rate > dataframe['close']:
slippage = (rate / dataframe['close'] - 1) * 100
if slippage < max_slip:
return True
else:
return False
return True
def custom_exit(self, pair: str, trade: 'Trade', current_time: 'datetime', current_rate: float, current_profit: float, **kwargs):
dataframe, _ = self.dp.get_analyzed_dataframe(pair, self.timeframe)
last_candle = dataframe.iloc[-1]
previous_candle_1 = dataframe.iloc[-2]
max_profit = (trade.max_rate - trade.open_rate) / trade.open_rate
max_loss = (trade.open_rate - trade.min_rate) / trade.min_rate
enter_tag = 'empty'
if hasattr(trade, 'enter_tag') and trade.entry_tag is not None:
enter_tag = trade.entry_tag
entry_tags = entry_tag.split()
pump_tags = ['adaptive ']
# main exit
if current_profit > 0.02:
if last_candle['momdiv_exit_1h'] == True:
return f'signal_profit_q_momdiv_1h( {enter_tag})'
if last_candle['momdiv_exit'] == True:
return f'signal_profit_q_momdiv( {enter_tag})'
if last_candle['momdiv_coh'] == True:
return f'signal_profit_q_momdiv_coh( {enter_tag})'
if last_candle['cti_40_1h'] > 0.844 and last_candle['r_84_1h'] > -20:
return f'signal_profit_cti_r( {enter_tag})'
# exit cti_r
if 0.012 > current_profit >= 0.0:
if last_candle['cti'] > self.exit_cti_r_cti.value and last_candle['r_14'] > self.exit_cti_r_r.value:
return f'exit_profit_cti_r_1( {enter_tag})'
# exit over 200
if last_candle['close'] > last_candle['ema_200']:
if current_profit > 0.01 and last_candle['rsi'] > 83:
return f'exit_profit_o_1 ( {enter_tag})'
# exit quick
if 0.06 > current_profit > 0.02 and last_candle['rsi'] > 80.0:
return f'signal_profit_q_1( {enter_tag})'
if 0.06 > current_profit > 0.02 and last_candle['cti'] > 0.95:
return f'signal_profit_q_2( {enter_tag})'
# exit recover
if max_loss > 0.06 and 0.05 > current_profit > 0.01 and (last_candle['rsi'] < 46):
return f'signal_profit_r_1( {enter_tag})'
# exit vwap dump
if 0.02 > current_profit > 0.005 and last_candle['ema_vwap_diff_50'] > 0.0 and (last_candle['ema_vwap_diff_50'] < 0.012):
return f'exit_vwap_dump( {enter_tag})'
# exit cmf div
if 0.02 > current_profit > 0.005 and last_candle['cmf'] > 0 and (last_candle['cmf_div_slow'] == 1):
return f'exit_cmf_div( {enter_tag})'
# stoploss
if current_profit < -0.025 and last_candle['close'] < last_candle['ema_200'] and (last_candle['cmf'] < self.exit_u_e_2_cmf.value) and ((last_candle['ema_200'] - last_candle['close']) / last_candle['close'] < self.exit_u_e_2_ema_close_delta.value) and (last_candle['rsi'] > previous_candle_1['rsi']) and (last_candle['rsi'] > last_candle['rsi_1h'] + self.exit_u_e_2_rsi.value):
return f'exit_stoploss_u_e_2( {enter_tag})'
# stoploss - deadfish
if current_profit < self.exit_deadfish_profit.value and last_candle['close'] < last_candle['ema_200'] and (last_candle['bb_width'] < self.exit_deadfish_bb_width.value) and (last_candle['close'] > last_candle['bb_middleband2'] * self.exit_deadfish_bb_factor.value) and (last_candle['volume_mean_12'] < last_candle['volume_mean_24'] * self.exit_deadfish_volume_factor.value) and (last_candle['cmf'] < 0.0):
return f'exit_stoploss_deadfish( {enter_tag})'
############################################################################
def populate_indicators(self, dataframe: DataFrame, metadata: dict) -> DataFrame:
assert self.dp, 'DataProvider is required for multiple timeframes.'
# Bollinger bands (hyperopt hard to implement)
bollinger2 = qtpylib.bollinger_bands(qtpylib.typical_price(dataframe), window=20, stds=2)
dataframe['bb_lowerband2'] = bollinger2['lower']
dataframe['bb_middleband2'] = bollinger2['mid']
dataframe['bb_upperband2'] = bollinger2['upper']
bollinger3 = qtpylib.bollinger_bands(qtpylib.typical_price(dataframe), window=20, stds=3)
dataframe['bb_lowerband3'] = bollinger3['lower']
dataframe['bb_middleband3'] = bollinger3['mid']
dataframe['bb_upperband3'] = bollinger3['upper']
### Other checks
dataframe['bb_width'] = (dataframe['bb_upperband2'] - dataframe['bb_lowerband2']) / dataframe['bb_middleband2']
dataframe['bb_delta'] = (dataframe['bb_lowerband2'] - dataframe['bb_lowerband3']) / dataframe['bb_lowerband2']
dataframe['bb_bottom_cross'] = qtpylib.crossed_below(dataframe['close'], dataframe['bb_lowerband3']).astype('int')
# CCI hyperopt
for val in self.entry_cci_length.range:
dataframe[f'cci_length_{val}'] = ta.CCI(dataframe, val)
dataframe['cci'] = ta.CCI(dataframe, 26)
dataframe['cci_long'] = ta.CCI(dataframe, 170)
# RMI hyperopt
for val in self.entry_rmi_length.range:
dataframe[f'rmi_length_{val}'] = RMI(dataframe, length=val, mom=4)
#dataframe['rmi'] = RMI(dataframe, length=8, mom=4)
# SRSI hyperopt ?
stoch = ta.STOCHRSI(dataframe, 15, 20, 2, 2)
dataframe['srsi_fk'] = stoch['fastk']
dataframe['srsi_fd'] = stoch['fastd']
# BinH
dataframe['closedelta'] = (dataframe['close'] - dataframe['close'].shift()).abs()
# SMA
dataframe['sma_15'] = ta.SMA(dataframe, timeperiod=15)
dataframe['sma_30'] = ta.SMA(dataframe, timeperiod=30)
# CTI
dataframe['cti'] = pta.cti(dataframe['close'], length=20)
# CRSI (3, 2, 100)
crsi_closechange = dataframe['close'] / dataframe['close'].shift(1)
crsi_updown = np.where(crsi_closechange.gt(1), 1.0, np.where(crsi_closechange.lt(1), -1.0, 0.0))
dataframe['crsi'] = (ta.RSI(dataframe['close'], timeperiod=3) + ta.RSI(crsi_updown, timeperiod=2) + ta.ROC(dataframe['close'], 100)) / 3
# CMF
dataframe['cmf'] = chaikin_money_flow(dataframe, 20)
# MFI
dataframe['mfi'] = ta.MFI(dataframe)
# EMA
dataframe['ema_8'] = ta.EMA(dataframe, timeperiod=8)
dataframe['ema_12'] = ta.EMA(dataframe, timeperiod=12)
dataframe['ema_13'] = ta.EMA(dataframe, timeperiod=13)
dataframe['ema_16'] = ta.EMA(dataframe, timeperiod=16)
dataframe['ema_20'] = ta.EMA(dataframe, timeperiod=20)
dataframe['ema_24'] = ta.EMA(dataframe, timeperiod=24)
dataframe['ema_26'] = ta.EMA(dataframe, timeperiod=26)
dataframe['ema_50'] = ta.EMA(dataframe, timeperiod=50)
dataframe['hma_50'] = qtpylib.hull_moving_average(dataframe['close'], window=50)
dataframe['ema_100'] = ta.EMA(dataframe, timeperiod=100)
dataframe['ema_200'] = ta.EMA(dataframe, timeperiod=200)
# SMA
dataframe['sma_9'] = ta.SMA(dataframe, timeperiod=9)
dataframe['sma_15'] = ta.SMA(dataframe, timeperiod=15)
dataframe['sma_21'] = ta.SMA(dataframe, timeperiod=21)
dataframe['sma_30'] = ta.SMA(dataframe, timeperiod=30)
dataframe['sma_75'] = ta.SMA(dataframe, timeperiod=75)
# VWAP
vwap_low, vwap, vwap_high = VWAPB(dataframe, 20, 1)
dataframe['vwap_upperband'] = vwap_high
dataframe['vwap_middleband'] = vwap
dataframe['vwap_lowerband'] = vwap_low
dataframe['vwap_width'] = (dataframe['vwap_upperband'] - dataframe['vwap_lowerband']) / dataframe['vwap_middleband'] * 100
# RSI
dataframe['rsi'] = ta.RSI(dataframe, timeperiod=14)
dataframe['rsi_fast'] = ta.RSI(dataframe, timeperiod=4)
dataframe['rsi_slow'] = ta.RSI(dataframe, timeperiod=20)
dataframe['rsi_84'] = ta.RSI(dataframe, timeperiod=84)
dataframe['rsi_112'] = ta.RSI(dataframe, timeperiod=112)
# Elliot
dataframe['EWO'] = EWO(dataframe, 50, 200)
# Cofi
stoch_fast = ta.STOCHF(dataframe, 5, 3, 0, 3, 0)
dataframe['fastd'] = stoch_fast['fastd']
dataframe['fastk'] = stoch_fast['fastk']
dataframe['adx'] = ta.ADX(dataframe)
# Heiken Ashi
heikinashi = qtpylib.heikinashi(dataframe)
dataframe['ha_open'] = heikinashi['open']
dataframe['ha_close'] = heikinashi['close']
dataframe['ha_high'] = heikinashi['high']
dataframe['ha_low'] = heikinashi['low']
## BB 40
bollinger2_40 = qtpylib.bollinger_bands(ha_typical_price(dataframe), window=40, stds=2)
dataframe['bb_lowerband2_40'] = bollinger2_40['lower']
dataframe['bb_middleband2_40'] = bollinger2_40['mid']
dataframe['bb_upperband2_40'] = bollinger2_40['upper']
# ClucHA
dataframe['bb_delta_cluc'] = (dataframe['bb_middleband2_40'] - dataframe['bb_lowerband2_40']).abs()
dataframe['ha_closedelta'] = (dataframe['ha_close'] - dataframe['ha_close'].shift()).abs()
dataframe['tail'] = (dataframe['ha_close'] - dataframe['ha_low']).abs()
dataframe['ema_slow'] = ta.EMA(dataframe['ha_close'], timeperiod=50)
dataframe['rocr'] = ta.ROCR(dataframe['ha_close'], timeperiod=28)
# Williams %R
dataframe['r_14'] = williams_r(dataframe, period=14)
dataframe['r_32'] = williams_r(dataframe, period=32)
dataframe['r_480'] = williams_r(dataframe, period=480)
# Volume
dataframe['volume_mean_4'] = dataframe['volume'].rolling(4).mean().shift(1)
dataframe['volume_mean_12'] = dataframe['volume'].rolling(12).mean().shift(1)
dataframe['volume_mean_24'] = dataframe['volume'].rolling(24).mean().shift(1)
# Diff
dataframe['ema_vwap_diff_50'] = (dataframe['ema_50'] - dataframe['vwap_lowerband']) / dataframe['ema_50']
# Dip Protection
dataframe['tpct_change_1'] = top_percent_change(dataframe, 1)
dataframe['tpct_change_2'] = top_percent_change(dataframe, 2)
dataframe['tpct_change_4'] = top_percent_change(dataframe, 4)
# MOMDIV
mom = momdiv(dataframe)
dataframe['momdiv_entry'] = mom['momdiv_entry']
dataframe['momdiv_exit'] = mom['momdiv_exit']
dataframe['momdiv_coh'] = mom['momdiv_coh']
dataframe['momdiv_col'] = mom['momdiv_col']
# MAMA, FAMA, KAMA
dataframe['hl2'] = (dataframe['high'] + dataframe['low']) / 2
dataframe['mama'], dataframe['fama'] = ta.MAMA(dataframe['hl2'], 0.25, 0.025)
dataframe['mama_diff'] = (dataframe['mama'] - dataframe['fama']) / dataframe['hl2']
dataframe['kama'] = ta.KAMA(dataframe['close'], 84)
# cmf div
dataframe['cmf_div_fast'] = dataframe['cmf'].rolling(12).max() >= dataframe['cmf'] * 1.025
dataframe['cmf_div_slow'] = dataframe['cmf'].rolling(20).max() >= dataframe['cmf'] * 1.025
# Modified Elder Ray Index
dataframe['moderi_96'] = moderi(dataframe, 96)
############################################################################
# BTC info
'\n Only applied to conditions prone to entry high such as high EWO conditions\n\n '
inf_tf = '5m'
informative = self.dp.get_pair_dataframe('BTC/USDT', timeframe=inf_tf)
informative_btc = informative.copy().shift(1)
dataframe['btc_close'] = informative_btc['close']
############################################################################
# 1h tf
inf_tf = '1h'
informative = self.dp.get_pair_dataframe(pair=metadata['pair'], timeframe=inf_tf)
# Heikin Ashi
inf_heikinashi = qtpylib.heikinashi(informative)
informative['ha_close'] = inf_heikinashi['close']
informative['rocr'] = ta.ROCR(informative['ha_close'], timeperiod=168)
# Bollinger bands
bollinger2 = qtpylib.bollinger_bands(qtpylib.typical_price(informative), window=20, stds=2)
informative['bb_lowerband2'] = bollinger2['lower']
informative['bb_middleband2'] = bollinger2['mid']
informative['bb_upperband2'] = bollinger2['upper']
informative['bb_width'] = (informative['bb_upperband2'] - informative['bb_lowerband2']) / informative['bb_middleband2']
# RSI
informative['rsi'] = ta.RSI(informative, timeperiod=14)
informative['rsi_28'] = ta.RSI(informative, timeperiod=28)
informative['rsi_42'] = ta.RSI(informative, timeperiod=42)
# EMA
informative['ema_20'] = ta.EMA(informative, timeperiod=20)
informative['ema_26'] = ta.EMA(informative, timeperiod=26)
informative['ema_50'] = ta.EMA(informative, timeperiod=50)
informative['ema_100'] = ta.EMA(informative, timeperiod=100)
informative['ema_200'] = ta.EMA(informative, timeperiod=200)
# Williams %R
informative['r_84'] = williams_r(informative, period=84)
informative['r_480'] = williams_r(informative, period=480)
# CTI
informative['cti'] = pta.cti(informative['close'], length=20)
informative['cti_40'] = pta.cti(informative['close'], length=40)
# CRSI (3, 2, 100)
crsi_closechange = informative['close'] / informative['close'].shift(1)
crsi_updown = np.where(crsi_closechange.gt(1), 1.0, np.where(crsi_closechange.lt(1), -1.0, 0.0))
informative['crsi'] = (ta.RSI(informative['close'], timeperiod=3) + ta.RSI(crsi_updown, timeperiod=2) + ta.ROC(informative['close'], 100)) / 3
# CMF
informative['cmf'] = chaikin_money_flow(informative, 20)
# MOMDIV
mom = momdiv(informative)
informative['momdiv_entry'] = mom['momdiv_entry']
informative['momdiv_exit'] = mom['momdiv_exit']
informative['momdiv_coh'] = mom['momdiv_coh']
informative['momdiv_col'] = mom['momdiv_col']
# S/R
res_series = informative['high'].rolling(window=5, center=True).apply(lambda row: is_resistance(row), raw=True).shift(2)
sup_series = informative['low'].rolling(window=5, center=True).apply(lambda row: is_support(row), raw=True).shift(2)
informative['res_level'] = Series(np.where(res_series, np.where(informative['close'] > informative['open'], informative['close'], informative['open']), float('NaN'))).ffill()
informative['res_hlevel'] = Series(np.where(res_series, informative['high'], float('NaN'))).ffill()
informative['sup_level'] = Series(np.where(sup_series, np.where(informative['close'] < informative['open'], informative['close'], informative['open']), float('NaN'))).ffill()
dataframe = merge_informative_pair(dataframe, informative, self.timeframe, inf_tf, ffill=True)
return dataframe
def populate_entry_trend(self, dataframe: DataFrame, metadata: dict) -> DataFrame:
conditions = []
dataframe.loc[:, 'enter_tag'] = ''
############################################################################
# Utils
is_pump_1 = dataframe['close'].rolling(48).max() >= dataframe['close'] * self.entry_pump_1_factor.value
pump_protection_strict = (dataframe['close'].rolling(48).max() >= dataframe['close'] * 1.125) & (dataframe['close'].rolling(288).max() >= dataframe['close'] * 1.225)
pump_protection_loose = (dataframe['close'].rolling(48).max() >= dataframe['close'] * 1.05) & (dataframe['close'].rolling(288).max() >= dataframe['close'] * 1.125)
pump_protection_mid = (dataframe['close'].rolling(48).max() >= dataframe['close'] * 1.1) & (dataframe['close'].rolling(288).max() >= dataframe['close'] * 1.1)
is_pump_4 = (dataframe['close'].rolling(48).max() >= dataframe['close'] * 1.075) & (dataframe['close'].rolling(288).max() >= dataframe['close'] * 1.175)
is_crash_1 = (dataframe['tpct_change_1'] < 0.08) & (dataframe['tpct_change_2'] < 0.08)
is_crash_2 = (dataframe['tpct_change_1'] < 0.06) & (dataframe['tpct_change_2'] < 0.06)
is_crash_3 = (dataframe['tpct_change_1'] < 0.055) & (dataframe['tpct_change_2'] < 0.055)
#is_sup_level_1 = (
#(dataframe['close'] > (dataframe['sup_level_1h'] * 0.93))
#)
#is_sup_level_2 = (
#(dataframe['close'] > (dataframe['sup_level_1h'] * 0.9))
#)
btc_dump = dataframe['btc_close'].rolling(24).max() >= dataframe['btc_close'] * 1.03
rsi_check = (dataframe['rsi_84'] < 60) & (dataframe['rsi_112'] < 60)
min_EWO_check = dataframe['EWO'] > -5.585
max_EWO_check = dataframe['EWO'] < 11.8
############################################################################
if self.entry_is_dip_enabled.value:
is_dip = (dataframe[f'rmi_length_{self.entry_rmi_length.value}'] < self.entry_rmi.value) & (dataframe[f'cci_length_{self.entry_cci_length.value}'] <= self.entry_cci.value) & (dataframe['srsi_fk'] < self.entry_srsi_fk.value)
if self.entry_is_break_enabled.value: #"entry_bb_delta": 0.025 0.036
#"entry_bb_width": 0.095 0.133
# from BinH
is_break = (dataframe['bb_delta'] > self.entry_bb_delta.value) & (dataframe['bb_width'] > self.entry_bb_width.value) & (dataframe['closedelta'] > dataframe['close'] * self.entry_closedelta.value / 1000) & (dataframe['close'] < dataframe['bb_lowerband3'] * self.entry_bb_factor.value) & is_crash_1 # from NFI next gen
is_local_uptrend = (dataframe['ema_26'] > dataframe['ema_12']) & (dataframe['ema_26'] - dataframe['ema_12'] > dataframe['open'] * self.entry_ema_diff.value) & (dataframe['ema_26'].shift() - dataframe['ema_12'].shift() > dataframe['open'] / 100) & (dataframe['close'] < dataframe['bb_lowerband2'] * self.entry_bb_factor.value) & (dataframe['closedelta'] > dataframe['close'] * self.entry_closedelta.value / 1000) & (dataframe['EWO'] < 4) & (dataframe['EWO'] > -2.5) # from SMA offset
is_ewo = (dataframe['rsi_fast'] < self.entry_rsi_fast.value) & (dataframe['close'] < dataframe['ema_8'] * self.entry_ema_low.value) & (dataframe['EWO'] > self.entry_ewo.value) & (dataframe['close'] < dataframe['ema_16'] * self.entry_ema_high.value) & (dataframe['rsi'] < self.entry_rsi.value)
is_ewo_2 = (dataframe['rsi_fast'] < self.entry_rsi_fast.value) & (dataframe['close'] < dataframe['ema_8'] * self.entry_ema_low_2.value) & (dataframe['EWO'] > self.entry_ewo_high.value) & (dataframe['close'] < dataframe['ema_16'] * self.entry_ema_high_2.value) & (dataframe['rsi'] < self.entry_rsi.value) & rsi_check & (btc_dump == 0)
is_vwap = (dataframe['close'] < dataframe['vwap_lowerband']) & (dataframe['vwap_width'] > self.entry_vwap_width.value) & (dataframe['closedelta'] > dataframe['close'] * self.entry_vwap_closedelta.value / 1000) & (dataframe['cti'] < self.entry_vwap_cti.value) & (dataframe['EWO'] > 8) & rsi_check & pump_protection_strict & (btc_dump == 0)
is_vwap_2 = (dataframe['close'] < dataframe['vwap_lowerband']) & (dataframe['vwap_width'] > self.entry_vwap_width_2.value) & (dataframe['closedelta'] > dataframe['close'] * self.entry_vwap_closedelta_2.value / 1000) & (dataframe['cti'] < self.entry_vwap_cti_2.value) & (dataframe['EWO'] > 4) & (dataframe['EWO'] < 8) & rsi_check & pump_protection_strict & (btc_dump == 0)
is_vwap_3 = (dataframe['close'] < dataframe['vwap_lowerband']) & (dataframe['vwap_width'] > self.entry_vwap_width_3.value) & (dataframe['closedelta'] > dataframe['close'] * self.entry_vwap_closedelta_3.value / 1000) & (dataframe['cti'] < self.entry_vwap_cti_3.value) & (dataframe['EWO'] < 4) & (dataframe['EWO'] > -2.5) & (dataframe['rsi_28_1h'] < 46) & pump_protection_loose & rsi_check & (btc_dump == 0)
is_VWAP = (dataframe['close'] < dataframe['vwap_lowerband']) & (dataframe['tpct_change_1'] > 0.04) & (dataframe['cti'] < -0.8) & (dataframe['rsi'] < 35) & rsi_check & (btc_dump == 0)
is_no_trend_4 = (dataframe['ema_26'] > dataframe['ema_12']) & (dataframe['ema_26'] - dataframe['ema_12'] > dataframe['open'] * self.entry_no_trend_factor_4.value) & (dataframe['ema_26'].shift() - dataframe['ema_12'].shift() > dataframe['open'] / 100) & (dataframe['cti'] < self.entry_no_trend_cti_4.value) & (dataframe['r_14'] < self.entry_no_trend_r14_4.value) & (dataframe['EWO'] < -4) & min_EWO_check & rsi_check
# Really Bear, don't engage until dump over
is_V_5 = (dataframe['bb_width'] > self.entry_V_bb_width_5.value) & (dataframe['cti'] < self.entry_V_cti_5.value) & (dataframe['r_14'] < self.entry_V_r14_5.value) & (dataframe['mfi'] < self.entry_V_mfi_5.value) & (dataframe['ema_vwap_diff_50'] > 0.215) & (dataframe['EWO'] < -10) & rsi_check
is_insta = (dataframe['bb_width_1h'] > 0.131) & (dataframe['r_14'] < -51) & (dataframe['r_84_1h'] < -70) & (dataframe['cti'] < -0.845) & (dataframe['cti_40_1h'] < -0.735) & (dataframe['close'].rolling(48).max() >= dataframe['close'] * 1.1) & (btc_dump == 0)
is_adaptive = (dataframe['kama'] > dataframe['fama']) & (dataframe['fama'] > dataframe['mama'] * self.entry_ada_mama_offset.value) & (dataframe['r_14'] < self.entry_ada_r_14.value) & (dataframe['mama_diff'] < self.entry_ada_mama_diff.value) & (dataframe['cti'] < self.entry_ada_cti.value) & pump_protection_strict & rsi_check
# NFI quick mode
is_nfi_32 = (dataframe['rsi_slow'] < dataframe['rsi_slow'].shift(1)) & (dataframe['rsi_fast'] < 46) & (dataframe['rsi'] > 19) & (dataframe['close'] < dataframe['sma_15'] * 0.942) & (dataframe['cti'] < -0.86)
is_nfi_33 = (dataframe['close'] < dataframe['ema_13'] * 0.978) & (dataframe['EWO'] > 8) & (dataframe['cti'] < -0.88) & (dataframe['rsi'] < 32) & (dataframe['r_14'] < -98.0) & (dataframe['volume'] < dataframe['volume_mean_4'] * 2.5)
is_nfix_39 = (dataframe['ema_200'] > dataframe['ema_200'].shift(12) * 1.01) & (dataframe['ema_200'] > dataframe['ema_200'].shift(48) * 1.07) & dataframe['bb_lowerband2_40'].shift().gt(0) & dataframe['bb_delta_cluc'].gt(dataframe['close'] * 0.056) & dataframe['closedelta'].gt(dataframe['close'] * 0.01) & dataframe['tail'].lt(dataframe['bb_delta_cluc'] * 0.5) & dataframe['close'].lt(dataframe['bb_lowerband2_40'].shift()) & dataframe['close'].le(dataframe['close'].shift()) & (dataframe['close'] > dataframe['ema_50'] * 0.912)
is_nfix_201 = (dataframe['rsi_slow'] < dataframe['rsi_slow'].shift()) & (dataframe['rsi_fast'] < 30.0) & (dataframe['ema_20_1h'] > dataframe['ema_26_1h']) & (dataframe['close'] < dataframe['sma_15'] * 0.953) & (dataframe['cti'] < -0.82) & (dataframe['cci'] < -210.0) & is_pump_1 & rsi_check
is_nfix_1 = ((dataframe['close'] - dataframe['open'].rolling(12).min()) / dataframe['open'].rolling(12).min() > 0.027) & (dataframe['rsi'] < 35.0) & (dataframe['r_32'] < -80.0) & (dataframe['mfi'] < 31.0) & (dataframe['rsi_1h'] > 30.0) & (dataframe['rsi_1h'] < 84.0) & (dataframe['r_480_1h'] > -99.0) & rsi_check
is_nfix_6 = (dataframe['close'] < dataframe['sma_15'] * 0.937) & (dataframe['crsi'] < 30.0) & (dataframe['rsi'] < dataframe['rsi'].shift(1)) & (dataframe['rsi'] < 28.0) & (dataframe['cti'] < -0.78) & (dataframe['cci'] < -200.0) & (dataframe['r_480_1h'] < -12.0) & rsi_check
is_nfix_7 = (dataframe['ema_50_1h'] > dataframe['ema_100_1h']) & (dataframe['close'] < dataframe['sma_30'] * 0.94) & (dataframe['close'] < dataframe['bb_lowerband2'] * 0.995) & (dataframe['cti'] < -0.9) & (dataframe['r_14'] < -95.0) & rsi_check
is_nfix_8 = (dataframe['close'] < dataframe['sma_30'] * 0.927) & (dataframe['EWO'] > 3.2) & (dataframe['rsi'] < 33.0) & (dataframe['cti'] < -0.9) & (dataframe['r_14'] < -97.0) & rsi_check
is_nfix_12 = (dataframe['close'] < dataframe['ema_20'] * 0.938) & (dataframe['EWO'] > 0.1) & (dataframe['rsi'] < 40.0) & (dataframe['cti'] < -0.9) & (dataframe['r_480_1h'] < -20.0) & (dataframe['volume'] < dataframe['volume_mean_4'] * 2.8) & (dataframe['close'] > dataframe['sup_level_1h'] * 0.9) & rsi_check & max_EWO_check
is_nfi7_33 = dataframe['moderi_96'] & (dataframe['cti'] < -0.88) & (dataframe['close'] < dataframe['ema_13'] * 0.988) & (dataframe['EWO'] > 6.4) & (dataframe['rsi'] < 32.0) & (dataframe['volume'] < dataframe['volume_mean_4'] * 2.0) & pump_protection_loose & rsi_check
is_nfi_sma_3 = (dataframe['bb_lowerband2_40'].shift() > 0) & (dataframe['bb_delta_cluc'] > dataframe['close'] * 0.059) & (dataframe['ha_closedelta'] > dataframe['close'] * 0.023) & (dataframe['tail'] < dataframe['bb_delta_cluc'] * 0.24) & (dataframe['close'] < dataframe['bb_lowerband2_40'].shift()) & (dataframe['close'] < dataframe['close'].shift()) & (btc_dump == 0)
is_BB_checked = is_dip & is_break
## condition append
conditions.append(is_BB_checked) # P
dataframe.loc[is_BB_checked, 'enter_tag'] += 'bb '
conditions.append(is_local_uptrend)
dataframe.loc[is_local_uptrend, 'enter_tag'] += 'local_uptrend '
conditions.append(is_ewo)
dataframe.loc[is_ewo, 'enter_tag'] += 'ewo '
conditions.append(is_ewo_2)
dataframe.loc[is_ewo_2, 'enter_tag'] += 'ewo2 '
conditions.append(is_no_trend_4)
dataframe.loc[is_no_trend_4, 'enter_tag'] += 'no_trend_4 '
conditions.append(is_vwap)
dataframe.loc[is_vwap, 'enter_tag'] += 'vwap '
conditions.append(is_vwap_2)
dataframe.loc[is_vwap_2, 'enter_tag'] += 'vwap_2 '
conditions.append(is_vwap_3)
dataframe.loc[is_vwap_3, 'enter_tag'] += 'vwap_3 '
conditions.append(is_VWAP)
dataframe.loc[is_VWAP, 'enter_tag'] += 'VWAP '
conditions.append(is_insta)
dataframe.loc[is_insta, 'enter_tag'] += 'insta '
conditions.append(is_adaptive)
dataframe.loc[is_adaptive, 'enter_tag'] += 'adaptive '
# NFI
conditions.append(is_nfi_32)
dataframe.loc[is_nfi_32, 'enter_tag'] += 'nfi_32 '
conditions.append(is_nfi_33)
dataframe.loc[is_nfi_33, 'enter_tag'] += 'nfi_33 '
conditions.append(is_nfi7_33)
dataframe.loc[is_nfi7_33, 'enter_tag'] += '7_33 '
conditions.append(is_nfi_sma_3)
dataframe.loc[is_nfi_sma_3, 'enter_tag'] += 'sma_3 '
# NFIX
conditions.append(is_nfix_1)
dataframe.loc[is_nfix_1, 'enter_tag'] += 'x_1 '
conditions.append(is_nfix_6)
dataframe.loc[is_nfix_6, 'enter_tag'] += 'x_6 '
conditions.append(is_nfix_7)
dataframe.loc[is_nfix_7, 'enter_tag'] += 'x_7 '
conditions.append(is_nfix_8)
dataframe.loc[is_nfix_8, 'enter_tag'] += 'x_8 '
conditions.append(is_nfix_12)
dataframe.loc[is_nfix_12, 'enter_tag'] += 'x_12 '
conditions.append(is_nfix_39)
dataframe.loc[is_nfix_39, 'enter_tag'] += 'x_39 '
conditions.append(is_nfix_201)
dataframe.loc[is_nfix_201, 'enter_tag'] += 'x_201 '
# Very Bear
conditions.append(is_V_5)
dataframe.loc[is_V_5, 'enter_tag'] += 'V_5 '
if conditions:
dataframe.loc[reduce(lambda x, y: x | y, conditions), 'enter_long'] = 1
return dataframe
def populate_exit_trend(self, dataframe: DataFrame, metadata: dict) -> DataFrame:
dataframe.loc[dataframe['volume'] > 0, 'exit_long'] = 0
return dataframe
# Chaikin Money Flow
def chaikin_money_flow(dataframe, n=20, fillna=False) -> Series:
"""Chaikin Money Flow (CMF)
It measures the amount of Money Flow Volume over a specific period.
http://stockcharts.com/school/doku.php?id=chart_school:technical_indicators:chaikin_money_flow_cmf
Args:
dataframe(pandas.Dataframe): dataframe containing ohlcv
n(int): n period.
fillna(bool): if fill nan values.
Returns:
pandas.Series: New feature generated.
"""
mfv = (dataframe['close'] - dataframe['low'] - (dataframe['high'] - dataframe['close'])) / (dataframe['high'] - dataframe['low'])
mfv = mfv.fillna(0.0) # float division by zero
mfv *= dataframe['volume']
cmf = mfv.rolling(n, min_periods=0).sum() / dataframe['volume'].rolling(n, min_periods=0).sum()
if fillna:
cmf = cmf.replace([np.inf, -np.inf], np.nan).fillna(0)
return Series(cmf, name='cmf')
# Mom DIV
def momdiv(dataframe: DataFrame, mom_length: int=10, bb_length: int=20, bb_dev: float=2.0, lookback: int=30) -> DataFrame:
mom: Series = ta.MOM(dataframe, timeperiod=mom_length)
upperband, middleband, lowerband = ta.BBANDS(mom, timeperiod=bb_length, nbdevup=bb_dev, nbdevdn=bb_dev, matype=0)
enter_long = qtpylib.crossed_below(mom, lowerband)
exit_long = qtpylib.crossed_above(mom, upperband)
hh = dataframe['high'].rolling(lookback).max()
ll = dataframe['low'].rolling(lookback).min()
coh = dataframe['high'] >= hh
col = dataframe['low'] <= ll
df = DataFrame({'momdiv_mom': mom, 'momdiv_upperb': upperband, 'momdiv_lowerb': lowerband, 'momdiv_entry': enter_long, 'momdiv_exit': exit_long, 'momdiv_coh': coh, 'momdiv_col': col}, index=dataframe['close'].index)
return df
class BB_RTR_dca(BB_RTR):
# DCA options
position_adjustment_enable = True
initial_safety_order_trigger = -0.08
max_safety_orders = 2
safety_order_step_scale = 0.5 #SS
safety_order_volume_scale = 1.6 #OS
# Auto compound calculation
max_dca_multiplier = 1 + max_safety_orders
if max_safety_orders > 0:
if safety_order_volume_scale > 1:
max_dca_multiplier = 2 + safety_order_volume_scale * (math.pow(safety_order_volume_scale, max_safety_orders - 1) - 1) / (safety_order_volume_scale - 1)
elif safety_order_volume_scale < 1:
max_dca_multiplier = 2 + safety_order_volume_scale * (1 - math.pow(safety_order_volume_scale, max_safety_orders - 1)) / (1 - safety_order_volume_scale)
# Let unlimited stakes leave funds open for DCA orders
def custom_stake_amount(self, pair: str, current_time: datetime, current_rate: float, proposed_stake: float, min_stake: float, max_stake: float, **kwargs) -> float:
if self.config['stake_amount'] == 'unlimited':
return proposed_stake / self.max_dca_multiplier
return proposed_stake
# DCA
def adjust_trade_position(self, trade: Trade, current_time: datetime, current_rate: float, current_profit: float, min_stake: float, max_stake: float, **kwargs):
if current_profit > self.initial_safety_order_trigger:
return None
count_of_entrys = trade.nr_of_successful_entries
if 1 <= count_of_entrys <= self.max_safety_orders:
safety_order_trigger = abs(self.initial_safety_order_trigger) * count_of_entrys
if self.safety_order_step_scale > 1:
safety_order_trigger = abs(self.initial_safety_order_trigger) + abs(self.initial_safety_order_trigger) * self.safety_order_step_scale * (math.pow(self.safety_order_step_scale, count_of_entrys - 1) - 1) / (self.safety_order_step_scale - 1)
elif self.safety_order_step_scale < 1:
safety_order_trigger = abs(self.initial_safety_order_trigger) + abs(self.initial_safety_order_trigger) * self.safety_order_step_scale * (1 - math.pow(self.safety_order_step_scale, count_of_entrys - 1)) / (1 - self.safety_order_step_scale)
if current_profit <= -1 * abs(safety_order_trigger):
try:
stake_amount = self.wallets.get_trade_stake_amount(trade.pair, None)
# This calculates base order size
stake_amount = stake_amount / self.max_dca_multiplier
# This then calculates current safety order size
stake_amount = stake_amount * math.pow(self.safety_order_volume_scale, count_of_entrys - 1)
amount = stake_amount / current_rate
logger.info(f'Initiating safety order entry #{count_of_entrys} for {trade.pair} with stake amount of {stake_amount} which equals {amount}')
return stake_amount
except Exception as exception:
logger.info(f'Error occured while trying to get stake amount for {trade.pair}: {str(exception)}')
return None
return None