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82391fcde10704c2b890ff4c997eb4b497af60b6
Freqtrade/Zeus_8_3_2_B_4_2.py
Jérôme Delacotte 82391fcde1 Calcul 20250101-20250714 737.222 159.166$
2025-09-12 23:38:01 +02:00

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# Zeus Strategy: First Generation of GodStra Strategy with maximum
# AVG/MID profit in USDT
# Author: @Mablue (Masoud Azizi)
# github: https://github.com/mablue/
# IMPORTANT: INSTALL TA BEFOUR RUN(pip install ta)
# freqtrade hyperopt --hyperopt-loss SharpeHyperOptLoss --spaces buy sell roi --strategy Zeus
# --- Do not remove these libs ---
from datetime import timedelta, datetime
from freqtrade.persistence import Trade
from freqtrade.strategy import (BooleanParameter, CategoricalParameter, DecimalParameter, stoploss_from_open,
IntParameter, IStrategy, merge_informative_pair, informative, stoploss_from_absolute)
import pandas as pd
import numpy as np
from pandas import DataFrame
from typing import Optional, Union, Tuple
import logging
import configparser
from technical import pivots_points
# --------------------------------
# Add your lib to import here test git
import ta
import talib.abstract as talib
import freqtrade.vendor.qtpylib.indicators as qtpylib
import requests
from datetime import timezone, timedelta
from scipy.signal import savgol_filter
from ta.trend import SMAIndicator, EMAIndicator, MACD, ADXIndicator
from collections import Counter
logger = logging.getLogger(__name__)
from tabulate import tabulate
# Couleurs ANSI de base
RED = "\033[31m"
GREEN = "\033[32m"
YELLOW = "\033[33m"
BLUE = "\033[34m"
MAGENTA = "\033[35m"
CYAN = "\033[36m"
RESET = "\033[0m"
def pprint_df(dframe):
print(tabulate(dframe, headers='keys', tablefmt='psql', showindex=False))
def normalize(df):
df = (df - df.min()) / (df.max() - df.min())
return df
class Zeus_8_3_2_B_4_2(IStrategy):
levels = [1, 2, 2, 4, 6, 8, 10, 12, 14, 16, 18, 20]
startup_candle_count = 12 * 24 * 2
# ROI table:
minimal_roi = {
"0": 0.564,
"567": 0.273,
"2814": 0.12,
"7675": 0
}
stakes = 40
# Stoploss:
stoploss = -1 # 0.256
# Custom stoploss
use_custom_stoploss = True
# Buy hypers
timeframe = '5m'
max_open_trades = 5
max_amount = 40
# DCA config
position_adjustment_enable = True
plot_config = {
"main_plot": {
"sma5_1h": {
"color": "white"
},
"sma5_1d": {
"color": "blue"
},
"sma20": {
"color": "yellow"
},
"bb_lowerband": {
"color": "#da59a6"},
"bb_upperband": {
"color": "#da59a6",
},
"sma10": {
"color": "blue"
}
},
"subplots": {
"Pct": {
"sma20_deriv1": {
'color': "green"
},
"down_pct": {
"color": "blue"
},
"down_pct_1h": {
"color": "red"
},
"down_pct_1d": {
"color": "red"
}
},
"Rsi": {
"rsi": {
"color": "pink"
},
"rsi_1h": {
"color": "red"
},
"rsi_1d": {
"color": "blue"
}
},
"Rsi_deriv": {
"rsi_deriv1_1h": {
"color": "red"
},
"rsi_deriv1_1d": {
"color": "blue"
},
},
"Down": {
"down_count_1h": {
"color": "green"
},
"up_count_1h": {
"color": "blue"
}
},
# "Diff": {
# "sma10_deriv1": {
# "color": "#74effc"
# }
# },
"smooth": {
'mid_smooth_deriv1_1d': {
"color": "blue"
},
'mid_smooth_1h_deriv1': {
"color": "red"
},
'mid_smooth_deriv2_1d': {
"color": "pink"
},
'mid_smooth_1h_deriv2': {
"color": "#da59a6"
}
}
}
}
columns_logged = False
pairs = {
pair: {
"first_buy": 0,
"last_buy": 0.0,
"last_min": 999999999999999.5,
"last_max": 0,
"trade_info": {},
"max_touch": 0.0,
"last_sell": 0.0,
'count_of_buys': 0,
'current_profit': 0,
'expected_profit': 0,
"last_candle": {},
"last_trade": None,
"last_count_of_buys": 0,
'base_stake_amount': 0,
'stop_buy': False,
'last_date': 0,
'stop': False,
'max_profit': 0,
'last_palier_index': -1,
'total_amount': 0
}
for pair in ["BTC/USDC", "ETH/USDC", "DOGE/USDC", "XRP/USDC", "SOL/USDC",
"BTC/USDT", "ETH/USDT", "DOGE/USDT", "XRP/USDT", "SOL/USDT"]
}
# 20 20 40 60 100 160 260 420
# 50 50 100 300 500
# fibo = [1, 1, 2, 3, 5, 8, 13, 21]
# my fibo
# 50 50 50 100 100 150 200 250 350 450 600 1050
fibo = [1, 1, 1, 2, 2, 3, 4, 5, 7, 9, 12, 16, 21]
baisse = [1, 2, 3, 5, 7, 10, 14, 19, 26, 35, 47, 63, 84]
# Ma suite 1 1 1 2 2 3 4 5 7 9 12 16 21
# Mise 50 50 50 100 100 150 200 250 350 450 600 800 1050
# Somme Mises 50 100 150 250 350 500 700 950 1300 1750 2350 3150 4200
# baisse 1 2 3 5 7 10 14 19 26 35 47 63 84
# factors = [1, 1.1, 1.25, 1.5, 2.0, 3]
# thresholds = [2, 5, 10, 20, 30, 50]
factors = [1, 1.25, 1.5, 2.0]
thresholds = [2, 5, 10, 20]
trades = list()
max_profit_pairs = {}
protection_percent_buy_lost = IntParameter(1, 10, default=5, space='protection')
protection_fibo = IntParameter(1, 10, default=2, space='protection')
sell_allow_decrease = DecimalParameter(0.005, 0.02, default=0.2, decimals=2, space='sell', optimize=True, load=True)
# Récupération des labels ordonnés
# labels = ['B5', 'B4', 'B3', 'B2', 'B1', 'N0', 'H1', 'H2', 'H3', 'H4', 'H5']
# index_labels = ['B5', 'B4', 'B3', 'B2', 'B1', 'N0', 'H1', 'H2', 'H3', 'H4', 'H5']
# ordered_labels = ['B5', 'B4', 'B3', 'B2', 'B1', 'N0', 'H1', 'H2', 'H3', 'H4', 'H5']
labels = ['B3', 'B2', 'B1', 'N0', 'H1', 'H2', 'H3']
index_labels = ['B3', 'B2', 'B1', 'N0', 'H1', 'H2', 'H3']
ordered_labels = ['B3', 'B2', 'B1', 'N0', 'H1', 'H2', 'H3']
label_to_index = {label: i for i, label in enumerate(ordered_labels)}
# # =========================================================================
# # variables pour probabilité
# # Bornes des quantiles pour
# ema_volume = [-8.9178, -0.0196, -0.0096, -0.0053, -0.0026, -0.0007, 0.0009, 0.0029, 0.0056, 0.0101, 0.0200, 3.8009]
# # Bornes des quantiles pour
# mid_smooth_1h_deriv1 = [-1.0482, -0.0571, -0.0336, -0.0206, -0.0113, -0.0033, 0.0044, 0.0127, 0.0225, 0.0356, 0.0591, 0.8335]
#
# ema_volume_mid_smooth_1h_deriv1_matrice = {
# 'B5': [28.0, 32.8, 33.6, 36.4, 35.5, 35.6, 40.1, 40.9, 45.9, 49.7, 52.2],
# 'B4': [33.9, 37.2, 38.6, 40.7, 39.7, 43.0, 46.2, 47.1, 51.9, 55.9, 61.1],
# 'B3': [36.4, 41.3, 39.1, 41.8, 44.6, 46.1, 50.3, 47.9, 47.6, 57.0, 58.5],
# 'B2': [40.7, 40.6, 40.9, 44.6, 48.0, 48.4, 48.5, 53.5, 53.0, 54.8, 53.3],
# 'B1': [37.5, 41.4, 48.0, 46.3, 48.5, 49.1, 53.7, 53.4, 56.4, 56.7, 62.8],
# 'N0': [47.0, 44.3, 45.6, 47.0, 52.9, 52.2, 55.7, 53.0, 57.6, 58.1, 63.4],
# 'H1': [44.1, 46.2, 49.4, 49.3, 52.2, 53.7, 58.2, 57.1, 59.0, 61.6, 61.3],
# 'H2': [51.0, 44.7, 49.4, 51.3, 54.9, 57.9, 56.7, 58.1, 60.3, 60.6, 65.6],
# 'H3': [50.5, 48.3, 49.9, 60.4, 57.8, 56.3, 60.2, 61.9, 62.2, 65.3, 68.3],
# 'H4': [43.1, 53.6, 58.1, 61.4, 58.7, 62.6, 61.3, 65.4, 67.5, 68.2, 71.4],
# 'H5': [56.6, 56.2, 57.7, 63.8, 64.8, 64.7, 66.5, 68.8, 70.9, 72.8, 76.6],
#
# }
#
# ema_volume_mid_smooth_1h_deriv1_matrice_df = pd.DataFrame(ema_volume_mid_smooth_1h_deriv1_matrice, index=index_labels)
# # Extraction de la matrice numérique
# ema_volume_mid_smooth_1h_deriv1_numeric_matrice = ema_volume_mid_smooth_1h_deriv1_matrice_df.reindex(index=ordered_labels, columns=ordered_labels).values
# =========================================================================
# paliers dérivées jour sma5
sma5_deriv1 = [-1.1726, -0.2131, -0.1012, -0.0330, 0.0169, 0.0815, 0.2000, 4.0335]
sma5_deriv2 = [-1.9190, -0.1388, -0.0644, -0.0202, 0.0209, 0.0646, 0.1377, 4.2987]
sma5_derive1_2_matrice = {
'B3': [8.6, 10.8, 34.6, 35.0, 58.8, 61.9, 91.2],
'B2': [0.0, 12.5, 9.1, 57.1, 63.3, 79.3, 89.5],
'B1': [6.1, 12.5, 22.0, 46.8, 61.5, 70.0, 100.0],
'N0': [0.0, 10.7, 37.0, 43.5, 75.0, 75.9, 100.0],
'H1': [0.0, 18.5, 32.4, 35.9, 76.8, 82.9, 92.0],
'H2': [0.0, 21.9, 16.0, 39.5, 69.7, 83.3, 100.0],
'H3': [9.5, 29.2, 41.2, 57.9, 53.8, 86.8, 92.3],
}
sma5_derive1_2_matrice_df = pd.DataFrame(sma5_derive1_2_matrice, index=index_labels)
# Extraction de la matrice numérique
sma5_derive1_2_numeric_matrice = sma5_derive1_2_matrice_df.reindex(index=ordered_labels, columns=ordered_labels).values
# paliers = {}
# =========================================================================
# Parameters hyperopt
# buy_mid_smooth_3_deriv1 = DecimalParameter(-0.1, 0.1, decimals=2, default=-0.06, space='buy')
# buy_mid_smooth_24_deriv1 = DecimalParameter(-0.6, 0, decimals=2, default=-0.03, space='buy')
buy_horizon_predict_1h = IntParameter(1, 6, default=2, space='buy')
# buy_level_predict_1h = IntParameter(2, 5, default=4, space='buy')
should_enter_trade_count = 0
def confirm_trade_entry(self, pair: str, order_type: str, amount: float, rate: float, time_in_force: str,
current_time: datetime, entry_tag: Optional[str], **kwargs) -> bool:
minutes = 0
if self.pairs[pair]['last_date'] != 0:
minutes = round(int((current_time - self.pairs[pair]['last_date']).total_seconds() / 60))
dataframe, _ = self.dp.get_analyzed_dataframe(pair, self.timeframe)
last_candle = dataframe.iloc[-1].squeeze()
last_candle_2 = dataframe.iloc[-2].squeeze()
last_candle_3 = dataframe.iloc[-3].squeeze()
# val = self.getProbaHausse144(last_candle)
# allow_to_buy = True #(not self.stop_all) #& (not self.all_down)
allow_to_buy = not self.pairs[pair]['stop'] # and val > self.buy_val.value #not last_candle['tendency'] in ('B-', 'B--') # (rate <= float(limit)) | (entry_tag == 'force_entry')
# if allow_to_buy:
# poly_func, x_future, y_future, count = self.polynomial_forecast(
# dataframe['mid_smooth_12'],
# window=self.buy_horizon_predict_1h.value * 12,
# degree=4,
# n_future=3)
#
# if count < 3:
# allow_to_buy = False
if not self.should_enter_trade(pair, last_candle, current_time):
allow_to_buy = False
if allow_to_buy:
self.trades = list()
self.pairs[pair]['first_buy'] = rate
self.pairs[pair]['last_buy'] = rate
self.pairs[pair]['max_touch'] = last_candle['close']
self.pairs[pair]['last_candle'] = last_candle
self.pairs[pair]['count_of_buys'] = 1
self.pairs[pair]['current_profit'] = 0
self.pairs[pair]['last_palier_index'] = -1
self.pairs[pair]['last_max'] = max(last_candle['close'], self.pairs[pair]['last_max'])
self.pairs[pair]['last_min'] = min(last_candle['close'], self.pairs[pair]['last_min'])
dispo = round(self.wallets.get_available_stake_amount())
self.printLineLog()
stake_amount = self.adjust_stake_amount(pair, last_candle)
self.pairs[pair]['total_amount'] = stake_amount
self.log_trade(
last_candle=last_candle,
date=current_time,
action=("🟩Buy" if allow_to_buy else "Canceled") + " " + str(minutes),
pair=pair,
rate=rate,
dispo=dispo,
profit=0,
trade_type=entry_tag,
buys=1,
stake=round(stake_amount, 2)
)
return allow_to_buy
def confirm_trade_exit(self, pair: str, trade: Trade, order_type: str, amount: float, rate: float,
time_in_force: str,
exit_reason: str, current_time, **kwargs, ) -> bool:
# allow_to_sell = (minutes > 30)
dataframe, _ = self.dp.get_analyzed_dataframe(pair, self.timeframe)
last_candle = dataframe.iloc[-1].squeeze()
allow_to_sell = (last_candle['percent'] < 0)
minutes = int(round((current_time - trade.date_last_filled_utc).total_seconds() / 60, 0))
if allow_to_sell:
self.trades = list()
self.pairs[pair]['last_count_of_buys'] = trade.nr_of_successful_entries # self.pairs[pair]['count_of_buys']
self.pairs[pair]['last_sell'] = rate
self.pairs[pair]['last_trade'] = trade
self.pairs[pair]['last_candle'] = last_candle
self.pairs[pair]['max_profit'] = 0
self.trades = list()
dispo = round(self.wallets.get_available_stake_amount())
# print(f"Sell {pair} {current_time} {exit_reason} dispo={dispo} amount={amount} rate={rate} open_rate={trade.open_rate}")
self.log_trade(
last_candle=last_candle,
date=current_time,
action="🟥Sell " + str(minutes),
pair=pair,
trade_type=exit_reason,
rate=last_candle['close'],
dispo=dispo,
profit=round(trade.calc_profit(rate, amount), 2)
)
self.pairs[pair]['current_profit'] = 0
self.pairs[pair]['total_amount'] = 0
self.pairs[pair]['count_of_buys'] = 0
self.pairs[pair]['max_touch'] = 0
self.pairs[pair]['last_buy'] = 0
self.pairs[pair]['last_date'] = current_time
self.pairs[pair]['last_palier_index'] = -1
self.pairs[pair]['last_trade'] = trade
self.pairs[pair]['current_trade'] = None
return (allow_to_sell) | (exit_reason == 'force_exit')
def custom_stake_amount(self, pair: str, current_time: datetime, current_rate: float,
proposed_stake: float, min_stake: float, max_stake: float,
**kwargs) -> float:
dataframe, _ = self.dp.get_analyzed_dataframe(pair=pair, timeframe=self.timeframe)
current_candle = dataframe.iloc[-1].squeeze()
adjusted_stake_amount = self.adjust_stake_amount(pair, current_candle)
# print(f"{pair} adjusted_stake_amount{adjusted_stake_amount}")
# Use default stake amount.
return adjusted_stake_amount
def custom_exit(self, pair: str, trade: Trade, current_time, current_rate, current_profit, **kwargs):
dataframe, _ = self.dp.get_analyzed_dataframe(pair, self.timeframe)
last_candle = dataframe.iloc[-1].squeeze()
last_candle_1h = dataframe.iloc[-13].squeeze()
before_last_candle = dataframe.iloc[-2].squeeze()
before_last_candle_2 = dataframe.iloc[-3].squeeze()
before_last_candle_12 = dataframe.iloc[-13].squeeze()
before_last_candle_24 = dataframe.iloc[-25].squeeze()
expected_profit = self.expectedProfit(pair, last_candle)
# print(f"current_time={current_time} current_profit={current_profit} expected_profit={expected_profit}")
max_touch_before = self.pairs[pair]['max_touch']
self.pairs[pair]['last_max'] = max(last_candle['close'], self.pairs[pair]['last_max'])
self.pairs[pair]['last_min'] = min(last_candle['close'], self.pairs[pair]['last_min'])
self.pairs[pair]['current_trade'] = trade
count_of_buys = trade.nr_of_successful_entries
# baisse = self.pairs[pair]['max_profit'] - current_profit
# mx = self.pairs[pair]['max_profit'] / 5
self.pairs[pair]['count_of_buys'] = count_of_buys
self.pairs[pair]['current_profit'] = current_profit
self.pairs[pair]['max_profit'] = max(self.pairs[pair]['max_profit'], current_profit)
if last_candle['sma20_deriv1_1d'] > 0 and last_candle['sma5_deriv1_1d'] > 0 and last_candle['mid_smooth_1h_deriv1'] > 0\
and last_candle['mid_smooth_1h_deriv2'] > 0:
return None
# if (last_candle['mid_smooth_deriv1'] >= 0):
# return None
# if (last_candle['tendency'] in ('H++', 'H+')) and (last_candle['rsi'] < 80):
# return None
#
# if (last_candle['sma20_deriv1'] < 0 and before_last_candle['sma20_deriv1'] >= 0) and (current_profit > expected_profit):
# return 'Drv_' + str(count_of_buys)
pair_name = self.getShortName(pair)
# if (current_profit > expected_profit) and last_candle['can_sell']:
# return 'Can_' + pair_name + '_' + str(count_of_buys)
# if 1 <= count_of_buys <= 3:
if ((before_last_candle_2['mid_smooth_3_deriv1'] <= before_last_candle['mid_smooth_3_deriv1'])
& (before_last_candle['mid_smooth_3_deriv1'] >= last_candle['mid_smooth_3_deriv1'])) \
and (current_profit > expected_profit):
return 'Drv3_' + pair_name + '_' + str(count_of_buys)
# if 4 <= count_of_buys <= 6:
# if ((before_last_candle_2['mid_smooth_12_deriv1'] <= before_last_candle['mid_smooth_12_deriv1'])
# & (before_last_candle['mid_smooth_12_deriv1'] >= last_candle['mid_smooth_12_deriv1'])) \
# and (current_profit > expected_profit):
# return 'Drv13_' + pair_name + '_' + str(count_of_buys)
#
# if 7 <= count_of_buys:
# if ((before_last_candle_24['sma24_deriv1_1h'] <= before_last_candle_12['sma24_deriv1_1h'])
# & (before_last_candle_12['sma24_deriv1_1h'] >= last_candle['sma24_deriv1_1h'])) \
# and (current_profit > expected_profit):
# return 'Drv24_' + pair_name + '_' + str(count_of_buys)
# if (baisse > mx) & (current_profit > expected_profit):
# self.trades = list()
# return 'mx_' + str(count_of_buys)
# if (last_candle['percent12'] <= -0.01) & (current_profit >= expected_profit):
# self.trades = list()
# return 'pft_' + str(count_of_buys)
self.pairs[pair]['max_touch'] = max(last_candle['close'], self.pairs[pair]['max_touch'])
def getShortName(self, pair):
return pair.replace("/USDT", '').replace("/USDC", '')
def informative_pairs(self):
# get access to all pairs available in whitelist.
pairs = self.dp.current_whitelist()
informative_pairs = [(pair, '1d') for pair in pairs]
informative_pairs += [(pair, '1h') for pair in pairs]
return informative_pairs
from typing import List
def multi_step_interpolate(self, pct: float, thresholds: List[float], factors: List[float]) -> float:
if pct <= thresholds[0]:
return factors[0]
if pct >= thresholds[-1]:
return factors[-1]
for i in range(1, len(thresholds)):
if pct <= thresholds[i]:
# interpolation linéaire entre thresholds[i-1] et thresholds[i]
return factors[i - 1] + (pct - thresholds[i - 1]) * (factors[i] - factors[i - 1]) / (
thresholds[i] - thresholds[i - 1])
# Juste au cas où (devrait jamais arriver)
return factors[-1]
# def interpolate_factor(self, pct: float, start_pct: float = 5, end_pct: float = 30,
# start_factor: float = 1.0, end_factor: float = 2.0) -> float:
# if pct <= start_pct:
# return start_factor
# if pct >= end_pct:
# return end_factor
# # interpolation linéaire
# return start_factor + (pct - start_pct) * (end_factor - start_factor) / (end_pct - start_pct)
def log_trade(self, action, pair, date, trade_type=None, rate=None, dispo=None, profit=None, buys=None, stake=None,
last_candle=None):
# Afficher les colonnes une seule fois
if self.config.get('runmode') == 'hyperopt':
return
if self.columns_logged % 10 == 0:
self.printLog(
f"| {'Date':<16} | {'Action':<10} |{'Pair':<5}| {'Trade Type':<18} |{'Rate':>8} | {'Dispo':>6} | {'Profit':>10} | {'Pct':>6} | {'max_touch':>11} | {'last_lost':>12} | {'last_max':>7}| {'last_max':>7}|{'Buys':>5}| {'Stake':>5} |"
f"Tdc|{'val':>6}|Distmax|s201d|s5_1d|s5_2d|s241h|s242h|smt1h|smt2h|"
)
self.printLineLog()
df = pd.DataFrame.from_dict(self.pairs, orient='index')
colonnes_a_exclure = ['last_candle', 'last_trade', 'last_palier_index', 'stop',
'trade_info', 'last_date', 'expected_profit', 'last_count_of_buys', 'base_stake_amount', 'stop_buy']
df_filtered = df[df['count_of_buys'] > 0].drop(columns=colonnes_a_exclure)
# df_filtered = df_filtered["first_buy", "last_max", "max_touch", "last_sell","last_buy", 'count_of_buys', 'current_profit']
print(df_filtered)
self.columns_logged += 1
date = str(date)[:16] if date else "-"
limit = None
# if buys is not None:
# limit = round(last_rate * (1 - self.fibo[buys] / 100), 4)
rsi = ''
rsi_pct = ''
# if last_candle is not None:
# if (not np.isnan(last_candle['rsi_1d'])) and (not np.isnan(last_candle['rsi_1h'])):
# rsi = str(int(last_candle['rsi_1d'])) + " " + str(int(last_candle['rsi_1h']))
# if (not np.isnan(last_candle['rsi_pct_1d'])) and (not np.isnan(last_candle['rsi_pct_1h'])):
# rsi_pct = str(int(10000 * last_candle['bb_mid_pct_1d'])) + " " + str(
# int(last_candle['rsi_pct_1d'])) + " " + str(int(last_candle['rsi_pct_1h']))
# first_rate = self.percent_threshold.value
# last_rate = self.threshold.value
# action = self.color_line(action, action)
sma5_1d = ''
sma5_1h = ''
sma5 = str(sma5_1d) + ' ' + str(sma5_1h)
last_lost = round((last_candle['close'] - self.pairs[pair]['max_touch']) / self.pairs[pair]['max_touch'], 3)
if buys is None:
buys = ''
max_touch = '' # round(last_candle['max12_1d'], 1) #round(self.pairs[pair]['max_touch'], 1)
pct_max = self.getPctFirstBuy(pair, last_candle)
total_counts = str(buys) + '/' + str(sum(pair_data['count_of_buys'] for pair_data in self.pairs.values()))
dist_max = round(100 * (last_candle['max12_1d'] - last_candle['min12_1d']) / last_candle['min12_1d'], 0)
# if trade_type is not None:
# if np.isnan(last_candle['rsi_1d']):
# string = ' '
# else:
# string = (str(int(last_candle['rsi_1d']))) + " " + str(int(last_candle['rsi_deriv1_1d']))
# trade_type = trade_type \
# + " " + string \
# + " " + str(int(last_candle['rsi_1h'])) \
# + " " + str(int(last_candle['rsi_deriv1_1h']))
# val144 = self.getProbaHausse144(last_candle)
# val1h = self.getProbaHausse1h(last_candle)
val = self.getProbaHausseSma5d(last_candle)
pct60 = round(100 * self.getPct60D(pair, last_candle), 2)
color = GREEN if profit > 0 else RED
color_sma20 = GREEN if last_candle['sma20_deriv1_1d'] > 0 else RED
color_sma5 = GREEN if last_candle['sma5_deriv1_1d'] > 0 else RED
color_sma5_2 = GREEN if last_candle['sma5_deriv2_1d'] > 0 else RED
color_sma5_1h = GREEN if last_candle['sma24_deriv1_1h'] > 0 else RED
color_sma5_2h = GREEN if last_candle['sma24_deriv2_1h'] > 0 else RED
color_smooth_1h = GREEN if last_candle['mid_smooth_1h_deriv1'] > 0 else RED
color_smooth2_1h = GREEN if last_candle['mid_smooth_1h_deriv2'] > 0 else RED
last_max = int(self.pairs[pair]['last_max']) if self.pairs[pair]['last_max'] > 1 else round(self.pairs[pair]['last_max'],3)
last_min = int(self.pairs[pair]['last_min']) if self.pairs[pair]['last_min'] > 1 else round(self.pairs[pair]['last_min'], 3)
profit=str(round(self.pairs[pair]['current_profit'], 2)) + '/' + str(profit)
self.printLog(
f"| {date:<16} |{action:<10} | {pair[0:3]:<3} | {trade_type or '-':<18} |{rate or '-':>9}| {dispo or '-':>6} "
f"|{color}{profit or '-':>10}{RESET}| {pct_max or '-':>6} | {round(self.pairs[pair]['max_touch'], 2) or '-':>11} | {last_lost or '-':>12} "
f"| {last_max or '-':>7} | {last_min or '-':>7} |{total_counts or '-':>5}|{stake or '-':>7}"
f"|{last_candle['tendency_12'] or '-':>3}|" # {last_candle['tendency_1h'] or '-':>3}|{last_candle['tendency_1d'] or '-':>3}"
# f"|{round(last_candle['mid_smooth_24_deriv1'],3) or '-':>6}|{round(last_candle['mid_smooth_1h_deriv1'],3) or '-':>6}|{round(last_candle['mid_smooth_deriv1_1d'],3) or '-' :>6}|"
# f"{round(last_candle['mid_smooth_24_deriv2'],3) or '-' :>6}|{round(last_candle['mid_smooth_1h_deriv2'],3) or '-':>6}|{round(last_candle['mid_smooth_deriv2_1d'],3) or '-':>6}|"
f"{round(val, 1) or '-' :>6}|"
f"{dist_max:>7}|{color_sma20}{round(last_candle['sma20_deriv1_1d'],2):>5}{RESET}"
f"|{color_sma5}{round(last_candle['sma5_deriv1_1d'],2):>5}{RESET}|{color_sma5_2}{round(last_candle['sma5_deriv2_1d'],2):>5}{RESET}"
f"|{color_sma5_1h}{round(last_candle['sma24_deriv1_1h'], 2):>5}{RESET}|{color_sma5_2h}{round(last_candle['sma24_deriv2_1h'], 2):>5}{RESET}"
f"|{color_smooth_1h}{round(last_candle['mid_smooth_1h_deriv1'],2):>5}{RESET}|{color_smooth2_1h}{round(last_candle['mid_smooth_1h_deriv2'],2):>5}{RESET}"
# f"|{last_candle['min60_1d']}|{last_candle['max60_1d']}"
)
def printLineLog(self):
# f"sum1h|sum1d|Tdc|Tdh|Tdd| drv1 |drv_1h|drv_1d|"
self.printLog(
f"+{'-' * 18}+{'-' * 12}+{'-' * 5}+{'-' * 20}+{'-' * 9}+{'-' * 8}+{'-' * 12}+{'-' * 8}+{'-' * 13}+{'-' * 14}+{'-' * 9}{'-' * 9}+{'-' * 5}+{'-' * 7}+"
f"{'-' * 3}"
# "+{'-' * 3}+{'-' * 3}
f"+{'-' * 6}+{'-' * 7}+{'-' * 5}+{'-' * 5}+{'-' * 5}+{'-' * 5}+{'-' * 5}+{'-' * 5}+"
)
def printLog(self, str):
if not self.dp.runmode.value in ('backtest', 'hyperopt', 'lookahead-analysis'):
logger.info(str)
else:
if not self.dp.runmode.value in ('hyperopt'):
print(str)
def add_tendency_column(self, dataframe: pd.DataFrame, suffixe='') -> pd.DataFrame:
def tag_by_derivatives(row):
d1 = row[f"mid_smooth{suffixe}_deriv1"]
d2 = row[f"mid_smooth{suffixe}_deriv2"]
d1_lim_inf = -0.01
d1_lim_sup = 0.01
if d1 >= d1_lim_inf and d1 <= d1_lim_sup: # and d2 >= d2_lim_inf and d2 <= d2_lim_sup:
return 'P' # Palier
if d1 == 0.0:
return 'DH' if d2 > 0 else 'DB' # Depart Hausse / Départ Baisse
if d1 > d1_lim_sup:
return 'H++' if d2 > 0 else 'H+' # Acceleration Hausse / Ralentissement Hausse
if d1 < d1_lim_inf:
return 'B--' if d2 < 0 else 'B-' # Accéleration Baisse / Ralentissement Baisse
return 'Mid'
dataframe[f"tendency{suffixe}"] = dataframe.apply(tag_by_derivatives, axis=1)
return dataframe
def populate_indicators(self, dataframe: DataFrame, metadata: dict) -> DataFrame:
# Add all ta features
pair = metadata['pair']
heikinashi = qtpylib.heikinashi(dataframe)
dataframe['haopen'] = heikinashi['open']
dataframe['haclose'] = heikinashi['close']
dataframe['hapercent'] = (dataframe['haclose'] - dataframe['haopen']) / dataframe['haclose']
dataframe['hapercent3'] = (dataframe['haclose'] - dataframe['haopen'].shift(3)) / dataframe['haclose'].shift(3)
dataframe['sma5'] = talib.SMA(dataframe, timeperiod=5)
dataframe['sma10'] = talib.SMA(dataframe, timeperiod=10)
self.calculeDerivees(dataframe, 'sma10')
dataframe['sma20'] = talib.SMA(dataframe, timeperiod=20)
self.calculeDerivees(dataframe, 'sma20')
dataframe['sma144'] = talib.SMA(dataframe, timeperiod=144)
self.calculeDerivees(dataframe, 'sma144')
dataframe["percent"] = (dataframe["close"] - dataframe["open"]) / dataframe["open"]
dataframe["percent3"] = (dataframe["close"] - dataframe["open"].shift(3)) / dataframe["open"].shift(3)
dataframe["percent5"] = (dataframe["close"] - dataframe["open"].shift(5)) / dataframe["open"].shift(5)
dataframe["percent12"] = (dataframe["close"] - dataframe["open"].shift(12)) / dataframe["open"].shift(12)
dataframe = self.calculateDerivation(dataframe, window=3, suffixe="_3")
# dataframe = self.calculateDerivation(dataframe, window=3, suffixe="_6")
dataframe["mid_re_smooth_3"] = self.conditional_smoothing(dataframe['mid_smooth_3'].dropna(),
threshold=0.0005).dropna()
self.calculeDerivees(dataframe, "mid_re_smooth_3")
dataframe = self.calculateDerivation(dataframe, window=12, suffixe="_12")
dataframe = self.calculateDerivation(dataframe, window=24, suffixe="_24", factor_1=1000, factor_2=10)
# print(metadata['pair'])
dataframe['rsi'] = talib.RSI(dataframe['close'], timeperiod=14)
self.calculeDerivees(dataframe, 'rsi')
dataframe['max48'] = talib.MAX(dataframe['close'], timeperiod=48)
dataframe['min36'] = talib.MIN(dataframe['close'], timeperiod=36)
dataframe['max36'] = talib.MAX(dataframe['close'], timeperiod=36)
dataframe['pct36'] = 100 * (dataframe['max36'] - dataframe['min36']) / dataframe['min36']
dataframe['maxpct36'] = talib.MAX(dataframe['pct36'], timeperiod=36)
# Bollinger Bands
bollinger = qtpylib.bollinger_bands(qtpylib.typical_price(dataframe), window=20, stds=2)
dataframe['bb_lowerband'] = bollinger['lower']
dataframe['bb_middleband'] = bollinger['mid']
dataframe['bb_upperband'] = bollinger['upper']
dataframe["bb_percent"] = (
(dataframe["close"] - dataframe["bb_lowerband"]) /
(dataframe["bb_upperband"] - dataframe["bb_lowerband"])
)
dataframe["bb_width"] = ((dataframe["bb_upperband"] - dataframe["bb_lowerband"]) / dataframe["bb_upperband"])
# Normalization
dataframe['bb_upperband5'] = dataframe['bb_upperband'].rolling(window=5).mean()
dataframe['bb_lowerband5'] = dataframe['bb_lowerband'].rolling(window=5).mean()
# dataframe = self.calculateRegression(dataframe, column='mid_smooth', window=24, degree=4, future_offset=12)
# dataframe = self.calculateRegression(dataframe, column='mid_smooth_24', window=24, degree=4, future_offset=12)
################### INFORMATIVE 1h
informative = self.dp.get_pair_dataframe(pair=metadata['pair'], timeframe="1h")
heikinashi = qtpylib.heikinashi(informative)
informative['haopen'] = heikinashi['open']
informative['haclose'] = heikinashi['close']
informative['hapercent'] = (informative['haclose'] - informative['haopen']) / informative['haclose']
# informative = self.calculateDerivation(informative, window=12)
# informative = self.apply_regression_derivatives(informative, column='mid', window=5, degree=4)
informative['volatility'] = talib.STDDEV(informative['close'], timeperiod=14) / informative['close']
self.calculeDerivees(informative, 'volatility')
informative['atr'] = (talib.ATR(informative['high'], informative['low'], informative['close'], timeperiod=14)) / \
informative['close']
self.calculeDerivees(informative, 'atr')
informative['rsi'] = talib.RSI(informative['close']) # , timeperiod=7)
informative['sma5'] = talib.SMA(informative, timeperiod=5)
informative['sma24'] = talib.SMA(informative, timeperiod=24)
self.calculeDerivees(informative, 'sma5')
self.calculeDerivees(informative, 'sma24')
# informative["mid_re_smooth"] = self.conditional_smoothing(informative['mid_smooth'].dropna(), threshold=0.0005).dropna()
# self.calculeDerivees(informative, "mid_re_smooth")
# self.calculateDownAndUp(informative, limit=0.0012)
# informative['futur_percent_3'] = 100 * ((informative['sma5'].shift(-3) - informative['sma5']) / informative['sma5'])
# if self.dp.runmode.value in ('backtest'):
# print("##################")
# print("# STAT HOUR")
# print("##################")
# self.calculateStats(informative, 'sma5_deriv1', 'futur_percent_3')
dataframe = merge_informative_pair(dataframe, informative, self.timeframe, "1h", ffill=True)
################### INFORMATIVE 1d
informative = self.dp.get_pair_dataframe(pair=metadata['pair'], timeframe="1d")
# informative = self.calculateDerivation(informative, window=5, factor_1=10000, factor_2=1000)
# informative['volatility'] = talib.STDDEV(informative['close'], timeperiod=14) / informative['close']
# informative['atr'] = (talib.ATR(informative['high'], informative['low'], informative['close'], timeperiod=14)) / informative['close']
# informative = self.apply_regression_derivatives(informative, column='mid', window=5, degree=4)
period_1d = 60
informative['max12'] = talib.MAX(informative['close'], timeperiod=12)
informative['max60'] = talib.MAX(informative['close'], timeperiod=period_1d)
informative['min12'] = talib.MIN(informative['close'], timeperiod=12)
informative['min60'] = talib.MIN(informative['close'], timeperiod=period_1d)
informative['volatility'] = talib.STDDEV(informative['close'], timeperiod=14) / informative['close']
self.calculeDerivees(informative, 'volatility')
informative["percent"] = (informative["close"] - informative["open"]) / informative["open"]
informative['rsi6'] = talib.RSI(informative['close'], timeperiod=6)
# self.calculeDerivees(informative, 'rsi')
#
informative['sma5'] = talib.SMA(informative, timeperiod=5)
informative['sma20'] = talib.SMA(informative, timeperiod=20)
self.calculeDerivees(informative, 'sma5', factor_1=10, factor_2=1)
self.calculeDerivees(informative, 'sma20', factor_1=10, factor_2=1)
informative['inversion_haute'] = (informative['sma20'].shift(2) < informative['sma20'].shift(1)) & (informative['sma20'].shift(1) > informative['sma20'])
informative['inversion_basse'] = (informative['sma20'].shift(2) > informative['sma20'].shift(1)) & (informative['sma20'].shift(1) < informative['sma20'])
# informative['futur_percent_3'] = 100 * ((informative['sma5'].shift(-3) - informative['sma5']) / informative['sma5'])
# if self.dp.runmode.value in ('backtest'):
# print("##################")
# print("# STAT DAY")
# print("##################")
# self.calculateStats(informative, 'sma5_deriv1', 'futur_percent_3')
# informative['close_smooth'] = self.conditional_smoothing(informative['mid'].dropna(), threshold=0.0015).dropna()
# informative['smooth'], informative['deriv1'], informative['deriv2'] = self.smooth_and_derivatives(informative['close_smooth'])
# informative['deriv1'] = 100 * informative['deriv1'] / informative['mid']
# informative['deriv2'] = 1000 * informative['deriv2'] / informative['mid']
# poly_func, x_future, y_future, count = self.polynomial_forecast(informative['sma5_deriv1_1d'], window=24, degree=4)
# informative['futur_percent_3'] = 100 * ((informative['sma5'].shift(-1) - informative['sma5']) / informative['sma5'])
# futur_cols = ['futur_percent_3']
# indic_1 = 'sma5_deriv1'
# indic_2 = 'sma5_deriv2'
# self.calculateProbabilite2Index(informative, futur_cols, indic_1, indic_2)
dataframe = merge_informative_pair(dataframe, informative, self.timeframe, "1d", ffill=True)
dataframe['last_price'] = dataframe['close']
dataframe['first_price'] = dataframe['close']
# dataframe['mid_price'] = (dataframe['last_price'] + dataframe['first_price']) / 2
# dataframe['close01'] = dataframe.iloc[-1]['close'] * 1.01
# dataframe['limit'] = dataframe['close']
count_buys = 0
if self.dp:
if self.dp.runmode.value in ('live', 'dry_run'):
self.getOpenTrades()
for trade in self.trades:
if trade.pair != pair:
continue
filled_buys = trade.select_filled_orders('buy')
count = 0
amount = 0
for buy in filled_buys:
if count == 0:
dataframe['first_price'] = buy.price
self.pairs[pair]['first_buy'] = buy.price
# dataframe['close01'] = buy.price * 1.01
# Order(id=2396, trade=1019, order_id=29870026652, side=buy, filled=0.00078, price=63921.01,
# status=closed, date=2024-08-26 02:20:11)
dataframe['last_price'] = buy.price
self.pairs[pair]['last_buy'] = buy.price
count = count + 1
amount += buy.price * buy.filled
# dataframe['mid_price'] = (dataframe['last_price'] + dataframe['first_price']) / 2
count_buys = count
# dataframe['limit'] = dataframe['last_price'] * (1 - self.baisse[count] / 100)
# dataframe['amount'] = amount
# dataframe['mid_smooth_tag'] = qtpylib.crossed_below(dataframe['mid_smooth_24_deriv1'], dataframe['mid_smooth_deriv2_24'])
# ===============================
# lissage des valeurs horaires
dataframe['mid_smooth_1h'] = dataframe['mid'].rolling(window=6).mean()
dataframe["mid_smooth_1h_deriv1"] = 100 * dataframe["mid_smooth_1h"].diff().rolling(window=6).mean() / dataframe['mid_smooth_1h']
dataframe["mid_smooth_1h_deriv2"] = 10 * dataframe["mid_smooth_1h_deriv1"].diff().rolling(window=6).mean()
# Compter les baisses / hausses consécutives
self.calculateDownAndUp(dataframe, limit=0.0001)
# dataframe["mid_re_smooth_1h"] = self.conditional_smoothing(dataframe['mid_smooth_1h'].dropna(), threshold=0.0005).dropna()
# self.calculeDerivees(dataframe, "mid_re_smooth_1h")
# dataframe['close_smooth_1h'] = self.conditional_smoothing(dataframe['mid'].rolling(window=3).mean().dropna(), threshold=0.0005)
# dataframe['smooth_1h'], dataframe['deriv1_1h'], dataframe['deriv2_1h'] = self.smooth_and_derivatives(dataframe['close_smooth_1h'])
# dataframe['deriv1_1h'] = 100 * dataframe['deriv1_1h'] / dataframe['mid_smooth_1h']
# dataframe['deriv2_1h'] = 1000 * dataframe['deriv2_1h'] / dataframe['mid_smooth_1h']
horizon_h = 12
dataframe['sma5_1h'] = dataframe['sma5_1h'].rolling(window=horizon_h).mean()
# dataframe['ema_volume'] = dataframe['ema_volume'].rolling(window=horizon_h).mean()
# dataframe['sma24_1h'] = dataframe['sma24_1h'].rolling(window=horizon_h).mean()
# dataframe['sma24_deriv1_1h'] = dataframe['sma24_deriv1_1h'].rolling(window=horizon_h).mean()
# dataframe = self.calculateRegression(dataframe, column='mid_smooth_1h', window=horizon_h * 12, degree=4, future_offset=24)
# Suppose que df['close'] est ton prix de clôture
# dataframe['close_smooth_24'] = self.conditional_smoothing(dataframe['mid'].rolling(24).mean().dropna(), threshold=0.0015)
# dataframe['smooth_24'], dataframe['smooth_24_deriv1'], dataframe['smooth_24_deriv2'] = self.smooth_and_derivatives(dataframe['close_smooth_24'])
# dataframe['smooth_24_deriv1'] = 100 * dataframe['smooth_24_deriv1'] / dataframe['mid_smooth_24']
# dataframe['smooth_24_deriv2'] = 100 * dataframe['smooth_24_deriv2'] / dataframe['mid_smooth_24']
dataframe['close_smooth'] = self.conditional_smoothing(dataframe['mid'].rolling(3).mean().dropna(),
threshold=0.001)
dataframe['smooth'], dataframe['deriv1'], dataframe['deriv2'] = self.smooth_and_derivatives(
dataframe['close_smooth'])
dataframe['deriv1'] = 100 * dataframe['deriv1'] / dataframe['mid']
dataframe['deriv2'] = 100 * dataframe['deriv2'] / dataframe['mid']
# ===============================
# Lissage des valeurs Journalières
horizon_d = 12 * 5 * 24
# dataframe['mid_smooth_1d'] = dataframe['mid_smooth_1d'].rolling(window=horizon_d * 5).mean()
# dataframe["mid_smooth_deriv1_1d"] = dataframe["mid_smooth_1d"].rolling(horizon_d).mean().diff() / horizon_d
# dataframe["mid_smooth_deriv2_1d"] = horizon_d * dataframe["mid_smooth_deriv1_1d"].rolling(horizon_d).mean().diff()
#
# dataframe['sma5_1d'] = dataframe['sma5_1d'].rolling(window=horizon_d).mean()
# dataframe['sma5_deriv1_1d'] = dataframe['sma5_deriv1_1d'].rolling(window=horizon_d).mean()
# dataframe['sma24_1d'] = dataframe['sma24_1d'].rolling(window=horizon_d).mean()
# dataframe['sma24_deriv1_1d'] = dataframe['sma24_deriv1_1d'].rolling(window=horizon_d).mean()
# dataframe = self.calculateRegression(dataframe, column='mid_smooth_1d', window=24, degree=4, future_offset=12)
# dataframe['percent_with_previous_day'] = 100 * (dataframe['close'] - dataframe['close_1d']) / dataframe['close']
# dataframe['percent_with_max_hour'] = 100 * (dataframe['close'] - dataframe['max12_1h']) / dataframe['close']
#
# horizon_h = 24 * 5
# dataframe['futur_percent_1h'] = 100 * ((dataframe['mid_smooth_1h'].shift(-12) - dataframe['mid_smooth_1h']) / dataframe['mid_smooth_1h']).rolling(horizon_h).mean()
# dataframe['futur_percent_3h'] = 100 * ((dataframe['close'].shift(-36) - dataframe['close']) / dataframe['close']).rolling(horizon_h).mean()
# dataframe['futur_percent_5h'] = 100 * ((dataframe['mid_smooth_1h'].shift(-60) - dataframe['mid_smooth_1h']) / dataframe['mid_smooth_1h']).rolling(horizon_h).mean()
# dataframe['futur_percent_12h'] = 100 * ((dataframe['mid_smooth_1h'].shift(-144) - dataframe['mid_smooth_1h']) / dataframe['mid_smooth_1h']).rolling(horizon_h).mean()
#
# dataframe['futur_percent_1d'] = 100 * (dataframe['close'].shift(-1) - dataframe['close']) / dataframe['close']
# dataframe['futur_percent_3d'] = 100 * (dataframe['close'].shift(-3) - dataframe['close']) / dataframe['close']
#
# self.calculateProbabilite2Index(dataframe, ['futur_percent_1d'], 'sma24_deriv1_1h', 'sma5_1d')
dataframe['ema_volume'] = 20 * (dataframe['volume'] * dataframe['percent']) / (
abs(dataframe['volume'].shift(1)) + abs(dataframe['volume'].shift(2)))
self.calculeDerivees(dataframe, 'ema_volume', factor_1=10, factor_2=1)
# if self.dp.runmode.value in ('backtest'):
# print("##################")
# print("# STAT DAY vs HOUR")
# print("##################")
# self.calculateProbabilite2Index(dataframe, futur_cols=['futur_percent_3h'], indic_1='ema_volume',
# indic_2='mid_smooth_1h_deriv1')
# dataframe['proba_hausse'] = dataframe.apply(lambda row: self.getProbaHausseEmaVolume(row), axis=1)
# dataframe['futur_percent_3'] = 100 * ((dataframe['sma5'].shift(-1) - dataframe['sma5']) / dataframe['sma5'])
# futur_cols = ['futur_percent_3']
# indic_1 = 'mid_smooth_1h_deriv1'
# indic_2 = 'mid_smooth_1h_deriv2'
# self.calculateProbabilite2Index(dataframe, futur_cols, indic_1, indic_2)
return dataframe
def calculeDerivees(self, dataframe, indic, factor_1=100, factor_2=10):
dataframe[f"{indic}_deriv1"] = factor_1 * dataframe[f"{indic}"].diff() / dataframe[f"{indic}"]
dataframe[f"{indic}_deriv2"] = factor_2 * dataframe[f"{indic}_deriv1"].diff()
def calculateDownAndUp(self, dataframe, limit=0.0001):
dataframe['down'] = dataframe['mid_smooth_1h_deriv1'] < limit # dataframe['hapercent'] <= limit
dataframe['up'] = dataframe['mid_smooth_1h_deriv1'] > limit # dataframe['hapercent'] >= limit
dataframe['down_count'] = - dataframe['down'].astype(int) * (
dataframe['down'].groupby((dataframe['down'] != dataframe['down'].shift()).cumsum()).cumcount() + 1)
dataframe['up_count'] = dataframe['up'].astype(int) * (
dataframe['up'].groupby((dataframe['up'] != dataframe['up'].shift()).cumsum()).cumcount() + 1)
# Créer une colonne vide
dataframe['down_pct'] = self.calculateUpDownPct(dataframe, 'down_count')
dataframe['up_pct'] = self.calculateUpDownPct(dataframe, 'up_count')
def calculateDerivation(self, dataframe, window=12, suffixe='', factor_1=100, factor_2=10):
dataframe['mid'] = dataframe['haopen'] + (dataframe['haclose'] - dataframe['haopen']) / 2
# 1. Calcul du lissage par moyenne mobile médiane
dataframe[f"mid_smooth{suffixe}"] = dataframe['haclose'].rolling(window=window).mean()
# 2. Dérivée première = différence entre deux bougies successives
dataframe[f"mid_smooth{suffixe}_deriv1"] = round(
factor_1 * dataframe[f"mid_smooth{suffixe}"].rolling(window=3).mean().diff() / dataframe[
f"mid_smooth{suffixe}"], 4)
# 3. Dérivée seconde = différence de la dérivée première
dataframe[f"mid_smooth{suffixe}_deriv2"] = round(
factor_2 * dataframe[f"mid_smooth{suffixe}_deriv1"].rolling(window=3).mean().diff(), 4)
dataframe = self.add_tendency_column(dataframe, suffixe)
return dataframe
def getOpenTrades(self):
# if len(self.trades) == 0:
self.trades = Trade.get_open_trades()
return self.trades
def populate_buy_trend(self, dataframe: DataFrame, metadata: dict) -> DataFrame:
pair = metadata['pair']
# self.getOpenTrades()
# expected_profit = self.expectedProfit(pair, dataframe.iloc[-1])
# self.getBinanceOrderBook(pair, dataframe)
# Calcul de la pente (différence entre deux bougies consécutives)
dataframe['bb_ub_slope'] = dataframe['bb_upperband'].diff()
# Détection d'une inversion (changement de signe de la pente)
# inversion = (
# (dataframe['bb_ub_slope'].shift(1).rolling(5).apply(
# lambda x: any(x[i] > 0 and x[i + 1] < 0 for i in range(len(x) - 1)))) == 1
# )
# On regarde si la bande supérieure a atteint un maximum il y a k bougies
# lookback = 5
# inversion = (dataframe['bb_upperband'] == dataframe['bb_upperband'].rolling(lookback).max())
# pente de la bb_upperband
dataframe['bb_ub_slope'] = dataframe['bb_upperband5'].diff()
# évènement "inversion vers le bas" (pente passe de >0 à <=0) sur chaque bougie
cross_down = (dataframe['bb_ub_slope'].shift(1) > 0) & (dataframe['bb_ub_slope'] <= 0)
dataframe['bb_cross_down'] = 10000 * cross_down * dataframe['bb_width'] \
* (dataframe['bb_lowerband'] - dataframe['bb_lowerband'].shift(1)) / dataframe['bb_lowerband']
# vrai si AU MOINS une inversion a eu lieu dans les 5 bougies *précédentes* (on exclut l'actuelle)
inversion_last5 = cross_down.shift(1).rolling(5, min_periods=1).max().astype(bool)
dataframe['inversion_last5'] = inversion_last5
N = 24 # nombre minimum de bougies avant inversion
rise_threshold = 1.0 # % de hausse à ne pas dépasser
# Calcul de la hausse minimale avant inversion
def compute_rise(idx):
if idx < N:
return 0
low_before = dataframe['close'].iloc[idx - N:idx].min() # min des N bougies avant inversion
return (dataframe['close'].iloc[idx] / low_before - 1) * 100
rise = [compute_rise(i) for i in range(len(dataframe))]
dataframe['rise_before_inversion'] = rise
# Filtre : inversion sans forte hausse avant
valid_inversion = inversion_last5 & (dataframe['rise_before_inversion'] <= rise_threshold)
# dataframe.loc[
# (
# (dataframe['percent'] > 0)
# & (dataframe['mid_smooth_deriv1'] >= dataframe['mid_smooth_deriv1'].shift(1))
# ), ['enter_long', 'enter_tag']] = (1, 'down')
factor = 1.01
if pair == "BTC/USDT" or pair == "BTC/USDC":
factor = factor / 2
dataframe.loc[
(
valid_inversion & inversion_last5
& (dataframe['hapercent'] > 0)
# valid_inversion
# ((dataframe['bb_cross_down'] < - 0.1)
# | (dataframe['bb_cross_down'].shift(1) < - 0.1)
# | (dataframe['bb_cross_down'].shift(2) < - 0.1)
# | (dataframe['bb_cross_down'].shift(3) < - 0.1)
# )
# & (dataframe['hapercent'] > 0)
# & (dataframe['close'] * factor < dataframe['bb_upperband5'])
#
#
# (dataframe['mid_smooth_1h_deriv1'] >= 0)
# & (dataframe['mid_smooth_1h_deriv1'] >= 0)
# & (dataframe['mid_smooth_1h_deriv1'].shift(1) <= 0)
# & (dataframe['mid_smooth_1h_deriv1'] >= dataframe['mid_smooth_1h_deriv1'].shift(1))
), ['enter_long', 'enter_tag']] = (1, 'smth')
dataframe['can_sell'] = np.where(((dataframe['mid_smooth_1h_deriv1'].shift(2) <= dataframe['mid_smooth_1h_deriv1'].shift(1))\
& (dataframe['mid_smooth_1h_deriv1'].shift(1) >= dataframe['mid_smooth_1h_deriv1'])), dataframe['close'], np.nan)
dataframe['can_buy'] = np.where(((dataframe['mid_smooth_12_deriv2'].shift(1) < 0)\
& (dataframe['mid_smooth_12_deriv2'].shift(1) <= dataframe['mid_smooth_12_deriv2'])), dataframe['close'], np.nan)
dataframe['test'] = np.where(dataframe['enter_long'] == 1, dataframe['close'] * 1.01, np.nan)
dataframe['perte_02'] = np.where((dataframe['percent3'] * 100 < -0.2), dataframe['close'], np.nan)
dataframe['mid_smooth_1h_deriv2_inv'] = np.where((dataframe['mid_smooth_1h_deriv2'].shift(2) >= dataframe['mid_smooth_1h_deriv2'].shift(1))
& (dataframe['mid_smooth_1h_deriv2'].shift(1) <= dataframe['mid_smooth_1h_deriv2']), dataframe['close'], np.nan)
# self.paliers = self.get_dca_stakes()
# if self.dp.runmode.value in ('backtest'):
# today = datetime.now().strftime("%Y-%m-%d-%H:%M:%S")
# dataframe.to_feather(f"user_data/data/binance/{today}-{metadata['pair'].replace('/', '_')}_df.feather")
# dataframe.to_csv(f"user_data/data/binance/{today}-{metadata['pair'].replace('/', '_')}_df.csv")
#
# df = dataframe
#
# # Colonnes à traiter
# # futur_cols = ['futur_percent_1h', 'futur_percent_3h', 'futur_percent_5h', 'futur_percent_12h']
# futur_cols = ['futur_percent_1h']
#
# # Tranches équitables par quantiles
#
# indic_1 = 'mid_smooth_24_deriv1'
# indic_2 = 'sma144_deriv1'
# #indic_2 = 'percent_with_max_hour'
# # indic_1 = 'mid_smooth_1h_deriv1'
# # indic_2 = 'sma5_deriv1_1d'
#
# self.calculateProbabilite2Index(df, futur_cols, indic_1, indic_2)
# if (self.getShortName(pair) == 'BTC'):
# for pct in range(0, 75):
# factor = self.multi_step_interpolate(pct, self.thresholds, self.factors)
# print(f"{pct} => {factor}")
return dataframe
def calculateProbabilite2Index(self, df, futur_cols, indic_1, indic_2):
# # Définition des tranches pour les dérivées
# bins_deriv = [-np.inf, -0.05, -0.01, 0.01, 0.05, np.inf]
# labels = ['forte baisse', 'légère baisse', 'neutre', 'légère hausse', 'forte hausse']
#
# # Ajout des colonnes bin (catégorisation)
# df[f"{indic_1}_bin"] = pd.cut(df['mid_smooth_1h_deriv1'], bins=bins_deriv, labels=labels)
# df[f"{indic_2}_bin"] = pd.cut(df['mid_smooth_deriv1_1d'], bins=bins_deriv, labels=labels)
#
# # Colonnes de prix futur à analyser
# futur_cols = ['futur_percent_1h', 'futur_percent_2h', 'futur_percent_3h', 'futur_percent_4h', 'futur_percent_5h']
#
# # Calcul des moyennes et des effectifs
# grouped = df.groupby([f"{indic_2}_bin", f"{indic_1}_bin"])[futur_cols].agg(['mean', 'count'])
#
# pd.set_option('display.width', 200) # largeur max affichage
# pd.set_option('display.max_columns', None)
pd.set_option('display.max_columns', None)
pd.set_option('display.width', 300) # largeur max affichage
# nettoyage
# series = df[f"{indic_2}"].dropna()
# unique_vals = df[f"{indic_2}"].nunique()
# print(unique_vals)
# print(df[f"{indic_2}"])
n = len(self.labels)
df[f"{indic_1}_bin"], bins_1h = pd.qcut(df[f"{indic_1}"], q=n, labels=self.labels, retbins=True,
duplicates='drop')
df[f"{indic_2}_bin"], bins_1d = pd.qcut(df[f"{indic_2}"], q=n, labels=self.labels, retbins=True,
duplicates='drop')
# Affichage formaté pour code Python
print(f"Bornes des quantiles pour {indic_1} : [{', '.join([f'{b:.4f}' for b in bins_1h])}]")
print(f"Bornes des quantiles pour {indic_2} : [{', '.join([f'{b:.4f}' for b in bins_1d])}]")
# Agrégation
grouped = df.groupby([f"{indic_2}_bin", f"{indic_1}_bin"], observed=True)[futur_cols].agg(['mean', 'count'])
# Affichage
with pd.option_context('display.max_rows', None, 'display.max_columns', None):
print(grouped.round(4))
# Ajout des probabilités de hausse
for col in futur_cols:
df[f"{col}_is_up"] = df[col] > 0
# Calcul de la proba de hausse
proba_up = df.groupby([f"{indic_2}_bin", f"{indic_1}_bin"], observed=True)[f"{col}_is_up"].mean().unstack()
print(f"\nProbabilité de hausse pour {col} (en %):")
with pd.option_context('display.max_rows', None, 'display.max_columns', None):
print((proba_up * 100).round(1))
# Affichage formaté des valeurs comme tableau Python
with pd.option_context('display.max_rows', None, 'display.max_columns', None):
df_formatted = (proba_up * 100).round(1)
print("data = {")
for index, row in df_formatted.iterrows():
row_values = ", ".join([f"{val:.1f}" for val in row])
print(f"'{index}': [{row_values}], ")
print("}")
def populate_sell_trend(self, dataframe: DataFrame, metadata: dict) -> DataFrame:
# dataframe.loc[
# (
# (dataframe['mid_smooth_deriv1'] == 0)
# & (dataframe['mid_smooth_deriv1'].shift(1) > 0)
# ), ['sell', 'exit_long']] = (1, 'sell_sma5_pct_1h')
return dataframe
def adjust_trade_position(self, trade: Trade, current_time: datetime,
current_rate: float, current_profit: float, min_stake: float,
max_stake: float, **kwargs):
# ne rien faire si ordre deja en cours
if trade.has_open_orders:
print("skip open orders")
return None
if (self.wallets.get_available_stake_amount() < 50): # or trade.stake_amount >= max_stake:
return 0
dataframe, _ = self.dp.get_analyzed_dataframe(trade.pair, self.timeframe)
last_candle = dataframe.iloc[-1].squeeze()
before_last_candle_12 = dataframe.iloc[-13].squeeze()
before_last_candle_24 = dataframe.iloc[-25].squeeze()
last_candle_3 = dataframe.iloc[-4].squeeze()
last_candle_previous_1h = dataframe.iloc[-13].squeeze()
# prépare les données
current_time = current_time.astimezone(timezone.utc)
open_date = trade.open_date.astimezone(timezone.utc)
dispo = round(self.wallets.get_available_stake_amount())
hours_since_first_buy = (current_time - trade.open_date_utc).seconds / 3600.0
days_since_first_buy = (current_time - trade.open_date_utc).days
hours = (current_time - trade.date_last_filled_utc).total_seconds() / 3600.0
count_of_buys = trade.nr_of_successful_entries
current_time_utc = current_time.astimezone(timezone.utc)
open_date = trade.open_date.astimezone(timezone.utc)
days_since_open = (current_time_utc - open_date).days
pair = trade.pair
pct_first = 0
total_counts = sum(pair_data['count_of_buys'] for pair_data in self.pairs.values() if not pair in ('BTC/USDT', 'BTC/USDC'))
if self.pairs[pair]['first_buy']:
pct_first = self.getPctFirstBuy(pair, last_candle)
pct = 0.012
if count_of_buys == 1:
pct_max = current_profit
else:
if self.pairs[trade.pair]['last_buy']:
pct_max = self.getPctLastBuy(pair, last_candle)
else:
pct_max = - pct
if pair in ('BTC/USDT', 'BTC/USDC') or count_of_buys <= 2:
lim = - pct - (count_of_buys * 0.001)
#lim = self.getLimitBuy(pair, last_candle, pct)
# lim = - (0.012 * (1 + round(count_of_buys / 5)) + 0.001 * (count_of_buys - 1))
# lim = - (0.012 + 0.001 * (count_of_buys - 1) + (0.002 * count_of_buys if count_of_buys > 10 else 0.001 * count_of_buys if count_of_buys > 5 else 0))
else:
pct = 0.05
lim = - pct - (count_of_buys * 0.001)
#lim = self.getLimitBuy(pair, last_candle, pct)
if (len(dataframe) < 1):
print("skip dataframe")
return None
if not self.should_enter_trade(pair, last_candle, current_time):
return None
# if self.dp.runmode.value in ('dry_run'):
# if pair not in ('BTC/USDT', 'BTC/USDC', 'XRP/USDT', 'XRP/USDC', 'ETH/USDT', 'ETH/USDC', 'SOL/USDT', 'SOL/USDT'):
# # print(f"skip pair {pair}")
# return None
# else:
# if pair not in ('BTC/USDT', 'BTC/USDC'):
# btc_count = self.pairs['BTC/USDT']['count_of_buys'] + self.pairs['BTC/USDC']['count_of_buys']
# # print(f"skip pair {pair}")
# if (btc_count > 4 or count_of_buys + 1 > btc_count) and pct_max < 0.20:
# return None
# # déclenche un achat si bougie rouge importante
# stake_amount = self.config.get('stake_amount')
# stake_amount = min(stake_amount, self.wallets.get_available_stake_amount())
# current_time = current_time.astimezone(timezone.utc)
# seconds_since_filled = (current_time - trade.date_last_filled_utc).total_seconds()
# pct = (last_candle['close'] - last_candle['open']) / (last_candle['open']) * 100
# if (
# stake_amount
# and pct <= - 1.10 #self.red_candle_pct
# and min_stake < stake_amount < max_stake
# and seconds_since_filled > (60 * 5)
# # and (last_candle["sma24_deriv1_1h"] > - 0.02)
# # and seconds_since_filled > (1 * 3600)
# # and count_of_entries < 10
# ):
# trade_type = last_candle['enter_tag'] if last_candle['enter_long'] == 1 else 'pct48'
# self.log_trade(
# last_candle=last_candle,
# date=current_time,
# action="Adjust 1",
# dispo=dispo,
# pair=trade.pair,
# rate=current_rate,
# trade_type=trade_type,
# profit=round(current_profit, 4), # round(current_profit * trade.stake_amount, 2),
# buys=trade.nr_of_successful_entries + 1,
# stake=round(stake_amount, 2)
# )
#
# self.pairs[trade.pair]['last_buy'] = current_rate
# self.pairs[trade.pair]['max_touch'] = last_candle['close']
# self.pairs[trade.pair]['last_candle'] = last_candle
# return stake_amount
#
# # déclenche un achat en conditions d'achat standard
# if (
# stake_amount
# and last_candle['close'] < last_candle['sma20']
# and last_candle['close'] < last_candle['open']
# and min_stake < stake_amount < max_stake
# and (last_candle["sma24_deriv1_1h"] > - 0.02)
# and seconds_since_filled > 23 * 3600 #self.staking_delay * 3600
# ):
# stake_amount = stake_amount * seconds_since_filled / (23 * 3600)
# trade_type = last_candle['enter_tag'] if last_candle['enter_long'] == 1 else 'pct48'
# self.log_trade(
# last_candle=last_candle,
# date=current_time,
# action="Adjust 2",
# dispo=dispo,
# pair=trade.pair,
# rate=current_rate,
# trade_type=trade_type,
# profit=round(current_profit, 4), # round(current_profit * trade.stake_amount, 2),
# buys=trade.nr_of_successful_entries + 1,
# stake=round(stake_amount, 2)
# )
#
# self.pairs[trade.pair]['last_buy'] = current_rate
# self.pairs[trade.pair]['max_touch'] = last_candle['close']
# self.pairs[trade.pair]['last_candle'] = last_candle
# return stake_amount
#
# return None
# index = self.get_palier_index(pct_first)
# if index is None:
# return None
# index = index -1
# lim, stake_amount = self.paliers[index] #- pct - (count_of_buys * 0.001)
# self.get_active_stake()
# val144 = self.getProbaHausse144(last_candle)
# val1h = self.getProbaHausse1h(last_candle)
# val = self.getProbaHausse(last_candle)
# buy = False
# previous = 0
# # current_profit=-0.001998 count_of_buys=1 pct_first=0.000 pct_palier=-0.629 pct_max=-0.002 lim=0.000
#
# for pct_palier, stake_amount in self.paliers:
# if abs(pct_palier) > abs(pct_first):
# lim = pct_palier
# break
# previous = pct_palier
# print(f"{trade.pair} current_profit={current_profit} count_of_buys={count_of_buys} pct_first={pct_first:.3f} pct_palier={pct_palier:.3f} pct_max={pct_max:.3f} lim={lim:.3f} ")
# if (days_since_open > count_of_buys) & (0 < count_of_buys <= max_buys) & (current_rate <= limit) & (last_candle['enter_long'] == 1):
# ['mid_smooth_1h_deriv1']
# sans cdt° ==>Avg. stake amount 276.516 USDT │ Total trade volume 175760.342 USDT 315 │ 1.17 │ 1204.156 │ 60.21│ 1 day, 13:45:00 │ 314 0 1 99.7 │ 0.787 USDT 0.02% │
# > - 0.03 ==>Avg. stake amount 259.702 USDT │ Total trade volume 149302.88 USDT 285 │ 1.19 │ 974.542 │ 48.73│ 1 day, 17:45:00 │ 284 0 1 99.6 │ 0.787 USDT 0.03% │
# > - 0.03 ==>Avg. stake amount 253.535 USDT │ Total trade volume 145312.936 USDT 284 │ 1.19 │ 1014.898 │ 50.74| 1 day, 17:54:00 │ 283 0 1 99.6 │ 0.684 USDT 0.02% │
# > - 0.015 ==>Avg. stake amount 249.107 USDT │ Total trade volume 138186.861 USDT 275 │ 1.20 │ 901.976 │ 45.1 │ 1 day, 19:17:00 │ 274 0 1 99.6 │ 0.684 USDT 0.02%
condition = (last_candle['sma5_deriv1_1h'] > 0 or count_of_buys <= 5) #and \
#(last_candle['mid_smooth_1h_deriv1'] > 0 and last_candle['mid_smooth_1h_deriv1'])
# last_candle['mid_smooth_1h_deriv1'] > - 0.05 #(last_candle['mid_smooth_3_deriv1'] > self.buy_mid_smooth_3_deriv1.value) and (last_candle['mid_smooth_24_deriv1'] > self.buy_mid_smooth_24_deriv1.value)
# (last_candle['enter_long'] == 1 & (count_of_buys < 3)) \
# or ((before_last_candle['mid_re_smooth_3_deriv1'] <= 0) & (last_candle['mid_re_smooth_3_deriv1'] >= 0) & (3 <= count_of_buys < 6)) \
# or ((before_last_candle['mid_smooth_1h_deriv1'] <= 0) & (last_candle['mid_smooth_1h_deriv1'] >= 0) & (6 <= count_of_buys))
limit_buy = 40
if (count_of_buys < limit_buy) and condition and (pct_max < lim) :
try:
# if 6 <= count_of_buys:
# if not ((before_last_candle_24['sma24_deriv1_1h'] > before_last_candle_12['sma24_deriv1_1h'])
# & (before_last_candle_12['sma24_deriv1_1h'] < last_candle['sma24_deriv1_1h'])):
# return None
# print(f"{trade.pair} current_profit={current_profit} count_of_buys={count_of_buys} pct_first={pct_first:.3f} pct_max={pct_max:.3f} lim={lim:.3f} index={index}")
# self.pairs[trade.pair]['last_palier_index'] = index
# # Appel de la fonction
# poly_func, x_future, y_future, count = self.polynomial_forecast(
# dataframe['mid_smooth_12'],
# window=self.buy_horizon_predict_1h.value * 12,
# degree=4)
#
# if count < 3:
# return None
max_amount = self.config.get('stake_amount') * 2.5
# stake_amount = min(stake_amount, self.wallets.get_available_stake_amount())
stake_amount = min(min(max_amount, self.wallets.get_available_stake_amount()),
self.adjust_stake_amount(pair,
last_candle) - 10 * pct_first / pct) # min(200, self.adjust_stake_amount(pair, last_candle) * self.fibo[count_of_buys])
trade_type = last_candle['enter_tag'] if last_candle['enter_long'] == 1 else 'pct48'
self.pairs[trade.pair]['count_of_buys'] += 1
self.pairs[pair]['total_amount'] += stake_amount
self.log_trade(
last_candle=last_candle,
date=current_time,
action="🟧 Loss -",
dispo=dispo,
pair=trade.pair,
rate=current_rate,
trade_type=trade_type,
profit=round(current_profit, 2), # round(current_profit * trade.stake_amount, 2),
buys=trade.nr_of_successful_entries + 1,
stake=round(stake_amount, 2)
)
self.pairs[trade.pair]['last_buy'] = current_rate
self.pairs[trade.pair]['max_touch'] = last_candle['close']
self.pairs[trade.pair]['last_candle'] = last_candle
# df = pd.DataFrame.from_dict(self.pairs, orient='index')
# colonnes_a_exclure = ['last_candle', 'last_trade', 'last_palier_index', 'stop',
# 'trade_info', 'last_date', 'expected_profit', 'last_count_of_buys', 'base_stake_amount', 'stop_buy']
# df_filtered = df[df['count_of_buys'] > 0].drop(columns=colonnes_a_exclure)
# # df_filtered = df_filtered["first_buy", "last_max", "max_touch", "last_sell","last_buy", 'count_of_buys', 'current_profit']
#
# print(df_filtered)
return stake_amount
except Exception as exception:
print(exception)
return None
# if (count_of_buys >= 6):
# self.log_trade(
# last_candle=last_candle,
# date=current_time,
# action="Sell",
# dispo=dispo,
# pair=trade.pair,
# rate=current_rate,
# trade_type="Stop loss",
# profit=round(current_profit, 4), # round(current_profit * trade.stake_amount, 2),
# buys=trade.nr_of_successful_entries + 1,
# stake=-trade.stake_amount
# )
# self.pairs[trade.pair]['last_buy'] = current_rate
# self.pairs[trade.pair]['max_touch'] = last_candle['close']
# self.pairs[trade.pair]['last_candle'] = last_candle
# return -trade.stake_amount
# if (count_of_buys < limit_buy and pct_max > pct and current_profit > 0.004) \
# and (last_candle['rsi_deriv1_1h'] >= -5) \
# and (last_candle['tendency'] in ('P', 'H++', 'DH', 'H+')) \
# and (last_candle['mid_smooth_deriv1'] > 0.015):
# try:
# trade_type = last_candle['enter_tag'] if last_candle['enter_long'] == 1 else 'pct48'
# self.log_trade(
# last_candle=last_candle,
# date=current_time,
# action="Gain +",
# dispo=dispo,
# pair=trade.pair,
# rate=current_rate,
# trade_type=trade_type,
# profit=round(current_profit, 4), # round(current_profit * trade.stake_amount, 2),
# buys=trade.nr_of_successful_entries + 1,
# stake=round(stake_amount, 2)
# )
# self.pairs[trade.pair]['last_buy'] = current_rate
# self.pairs[trade.pair]['max_touch'] = last_candle['close']
# self.pairs[trade.pair]['last_candle'] = last_candle
# return stake_amount
# except Exception as exception:
# print(exception)
# return None
return None
def getPctFirstBuy(self, pair, last_candle):
return round((last_candle['close'] - self.pairs[pair]['first_buy']) / self.pairs[pair]['first_buy'], 3)
def getPctLastBuy(self, pair, last_candle):
return round((last_candle['close'] - self.pairs[pair]['last_buy']) / self.pairs[pair]['last_buy'], 4)
def getPct60D(self, pair, last_candle):
return round((last_candle['max60_1d'] - last_candle['min60_1d']) / last_candle['max60_1d'], 4)
def getPctClose60D(self, pair, last_candle):
if last_candle['close'] > last_candle['max60_1d']:
return 1
if last_candle['close'] < last_candle['min60_1d']:
return 0
return round((last_candle['close'] - last_candle['min60_1d']) / (last_candle['max60_1d'] - last_candle['min60_1d']), 4)
def getLimitBuy(self, pair, last_candle, first_pct):
count_of_buys = self.pairs[pair]['count_of_buys']
pct60 = self.getPct60D(pair, last_candle) # exemple 0.3 pour 30%
if (pct60 < 0.05):
lim = - first_pct - (count_of_buys * 0.001 * 0.05 / 0.05)
else:
# 0.1
# 0.4
lim = - first_pct - (count_of_buys * 0.001 * pct60 / 0.05)
return lim
# def getProbaHausseEmaVolume(self, last_candle):
# value_1 = self.getValuesFromTable(self.ema_volume, last_candle['ema_volume'])
# value_2 = self.getValuesFromTable(self.mid_smooth_1h_deriv1, last_candle['mid_smooth_1h_deriv1'])
#
# val = self.approx_val_from_bins(
# matrice=self.ema_volume_mid_smooth_1h_deriv1_matrice_df,
# numeric_matrice=self.ema_volume_mid_smooth_1h_deriv1_numeric_matrice,
# row_label=value_2,
# col_label=value_1
# )
# return val
def getProbaHausseSma5d(self, last_candle):
value_1 = self.getValuesFromTable(self.sma5_deriv1, last_candle['sma5_deriv1_1d'])
value_2 = self.getValuesFromTable(self.sma5_deriv2, last_candle['sma5_deriv2_1d'])
# print(f"{last_candle['sma5_deriv1_1d']} => {value_1} / {last_candle['sma5_deriv2_1d']} => {value_2}")
val = self.approx_val_from_bins(
matrice=self.sma5_derive1_2_matrice_df,
numeric_matrice=self.sma5_derive1_2_numeric_matrice,
row_label=value_2,
col_label=value_1
)
return val
def adjust_stake_amount(self, pair: str, last_candle: DataFrame):
# Calculer le minimum des 14 derniers jours
base_stake_amount = self.config.get('stake_amount') # Montant de base configuré
# pct60 = round(100 * self.getPctClose60D(pair, last_candle), 2)
if not pair in ('BTC/USDT', 'BTC/USDC'):
# factors = [1, 1.2, 1.3, 1.4]
if self.pairs[pair]['count_of_buys'] == 0:
pctClose60 = self.getPctClose60D(pair, last_candle)
adjusted_stake_amount = max(base_stake_amount / 5, base_stake_amount * (1 - pctClose60))
else:
adjusted_stake_amount = self.pairs[pair]['first_amount']
else :
first_price = self.pairs[pair]['first_buy']
if (first_price == 0):
first_price = last_candle['close']
last_max = last_candle['max12_1d']
pct = 5
if last_max > 0:
pct = 100 * (last_max - first_price) / last_max
factor = self.multi_step_interpolate(pct, self.thresholds, self.factors)
adjusted_stake_amount = base_stake_amount * factor # max(base_stake_amount, min(100, base_stake_amount * percent_4))
# pct = 100 * abs(self.getPctFirstBuy(pair, last_candle))
#
# factor = self.multi_step_interpolate(pct, self.thresholds, self.factors)
if self.pairs[pair]['count_of_buys'] == 0:
self.pairs[pair]['first_amount'] = adjusted_stake_amount
return adjusted_stake_amount
def calculateAmountSliding(self, pair, last_candle):
val = last_candle['close']
min_sliding = min(last_candle['min60_1d'], val)
max_sliding = max(last_candle['max60_1d'], val)
min_abs = self.pairs[pair]['last_min']
max_abs = self.pairs[pair]['last_max']
full = self.wallets.get_total_stake_amount()
stake = full / self.stakes
out_min = stake / 2
out_max = stake * 2
# Clamp sliding range within absolute bounds
min_sliding = max(min_sliding, min_abs)
max_sliding = min(max_sliding, max_abs)
# Avoid division by zero
if max_sliding == min_sliding:
return out_max # Or midpoint, or default value
# Inverse linear interpolation
position = (val - min_sliding) / (max_sliding - min_sliding)
return out_max - position * (out_max - out_min)
def calculatePctSliding(self, pair, last_candle):
val = last_candle['close']
min_sliding = last_candle['min60_1d']
max_sliding = last_candle['max60_1d']
min_abs = self.pairs[pair]['last_min']
max_abs = self.pairs[pair]['last_max']
out_min = 0.025
out_max = 0.08
# Clamp sliding range within absolute bounds
min_sliding = max(min_sliding, min_abs)
max_sliding = min(max_sliding, max_abs)
# Avoid division by zero
if max_sliding == min_sliding:
return out_max # Or midpoint, or default value
# Inverse linear interpolation
position = (val - min_sliding) / (max_sliding - min_sliding)
return out_max - position * (out_max - out_min)
def expectedProfit(self, pair: str, last_candle: DataFrame):
pct_to_max = 0.004 + 0.001 * self.pairs[pair]['count_of_buys']
# pctClose60 = self.getPctClose60D(pair, last_candle)
# max_60 = last_candle['max60_1d']
# if last_candle['close'] < max_60:
# pct_to_max = 0.25 * (max_60 - last_candle['close']) / max_60
# pct_to_max = pct_to_max * (2 - pctClose60)
expected_profit = max(0.004, pct_to_max) # 0.004 + 0.002 * self.pairs[pair]['count_of_buys'] #min(0.01, first_max)
# print(
# f"Expected profit price={current_price:.4f} min_max={min_max:.4f} min_14={min_14_days:.4f} max_14={max_14_days:.4f} percent={percent:.4f} expected_profit={expected_profit:.4f}")
return expected_profit
def calculateUpDownPct(self, dataframe, key):
down_pct_values = np.full(len(dataframe), np.nan)
# Remplir la colonne avec les bons calculs
for i in range(len(dataframe)):
shift_value = abs(int(dataframe[key].iloc[i])) # Récupérer le shift actuel
if i - shift_value > 1: # Vérifier que le shift ne dépasse pas l'index
down_pct_values[i] = 100 * (dataframe['close'].iloc[i] - dataframe['close'].iloc[i - shift_value]) / \
dataframe['close'].iloc[i - shift_value]
return down_pct_values
# ✅ Première dérivée(variation ou pente)
# Positive: la courbe est croissante → tendance haussière.
# Négative: la courbe est décroissante → tendance baissière.
# Proche de 0: la courbe est plate → marché stable ou en transition.
#
# Applications:
# Détecter les points dinflexion(changement de tendance) quand elle sannule.\
# Analyser la vitesse dun mouvement(plus elle est forte, plus le mouvement est impulsif).
#
# ✅ Seconde dérivée(accélération ou concavité)
# Positive: la pente augmente → accélération de la hausse ou ralentissement de la baisse.
# Négative: la pente diminue → accélération de la baisse ou ralentissement de la hausse.
# Changement de signe: indique souvent un changement de courbure, utile pour prévoir des retournements.
#
# Exemples:
# 🟢 Dérivée 1 > 0 et dérivée 2 > 0: tendance haussière qui saccélère.
# 🟡 Dérivée 1 > 0 et dérivée 2 < 0: tendance haussière qui ralentit → essoufflement potentiel.
# 🔴 Dérivée 1 < 0 et dérivée 2 < 0: tendance baissière qui saccélère.
# 🟠 Dérivée 1 < 0 et dérivée 2 > 0: tendance baissière qui ralentit → possible bottom.
#
# Filtrer les signaux: ne prendre un signal haussier que si dérivée1 > 0 et dérivée2 > 0.
# Détecter les zones de retournement: quand dérivée1 ≈ 0 et que dérivée2 change de signe.
def calculateRegression(self,
dataframe: DataFrame,
column='close',
window=50,
degree=3,
future_offset: int = 10 # projection à n bougies après
) -> DataFrame:
df = dataframe.copy()
regression_fit = []
regression_future_fit = []
regression_fit = []
regression_future_fit = []
for i in range(len(df)):
if i < window:
regression_fit.append(np.nan)
regression_future_fit.append(np.nan)
continue
# Fin de la fenêtre dapprentissage
end_index = i
start_index = i - window
y = df[column].iloc[start_index:end_index].values
# Si les données sont insuffisantes (juste par précaution)
if len(y) < window:
regression_fit.append(np.nan)
regression_future_fit.append(np.nan)
continue
# x centré pour meilleure stabilité numérique
x = np.linspace(-1, 1, window)
coeffs = np.polyfit(x, y, degree)
poly = np.poly1d(coeffs)
# Calcul point présent (dernier de la fenêtre)
x_now = x[-1]
regression_fit.append(poly(x_now))
# Calcul point futur, en ajustant si on dépasse la fin
remaining = len(df) - i - 1
effective_offset = min(future_offset, remaining)
x_future = x_now + (effective_offset / window) * 2 # respect du même pas
regression_future_fit.append(poly(x_future))
df[f"{column}_regression"] = regression_fit
# 2. Dérivée première = différence entre deux bougies successives
df[f"{column}_regression_deriv1"] = round(100 * df[f"{column}_regression"].diff() / df[f"{column}_regression"],
4)
# 3. Dérivée seconde = différence de la dérivée première
df[f"{column}_regression_deriv2"] = round(
10 * df[f"{column}_regression_deriv1"].rolling(int(window / 4)).mean().diff(), 4)
df[f"{column}_future_{future_offset}"] = regression_future_fit
# # 2. Dérivée première = différence entre deux bougies successives
# df[f"{column}_future_{future_offset}_deriv1"] = round(100 * df[f"{column}_future_{future_offset}"].diff() / df[f"{column}_future_{future_offset}"], 4)
#
# # 3. Dérivée seconde = différence de la dérivée première
# df[f"{column}_future_{future_offset}_deriv2"] = round(10 * df[f"{column}_future_{future_offset}_deriv1"].rolling(int(window / 4)).mean().diff(), 4)
return df
def getValuesFromTable(self, values, value):
for i in range(len(values) - 1):
if values[i] <= value < values[i + 1]:
return self.labels[i]
return self.labels[-1] # cas limite pour la borne max
# def interpolated_val_from_bins(self, row_pos, col_pos):
# """
# Renvoie une approximation interpolée (bilinéaire) d'une valeur dans la matrice
# à partir de positions flottantes dans l'index (ligne) et les colonnes.
#
# Parameters:
# matrix_df (pd.DataFrame): Matrice des probabilités (index/colonnes = labels).
# row_pos (float): Position réelle de la ligne (0 = B5, 10 = H5).
# col_pos (float): Position réelle de la colonne (0 = B5, 10 = H5).
#
# Returns:
# float: Valeur interpolée, ou NaN si en dehors des bornes.
# """
#
# # Labels ordonnés
# n = len(self.labels)
#
# # Vérification des limites
# if not (0 <= row_pos <= n - 1) or not (0 <= col_pos <= n - 1):
# return np.nan
#
# # Conversion des labels -> matrice
# matrix = self.smooth_smadiff_matrice_df.reindex(index=self.labels, columns=self.labels).values
#
# # Coordonnées entières (inférieures)
# i = int(np.floor(row_pos))
# j = int(np.floor(col_pos))
#
# # Coefficients pour interpolation
# dx = row_pos - i
# dy = col_pos - j
#
# # Précautions sur les bords
# if i >= n - 1: i = n - 2; dx = 1.0
# if j >= n - 1: j = n - 2; dy = 1.0
#
# # Récupération des 4 valeurs voisines
# v00 = matrix[i][j]
# v10 = matrix[i + 1][j]
# v01 = matrix[i][j + 1]
# v11 = matrix[i + 1][j + 1]
#
# # Interpolation bilinéaire
# interpolated = (
# (1 - dx) * (1 - dy) * v00 +
# dx * (1 - dy) * v10 +
# (1 - dx) * dy * v01 +
# dx * dy * v11
# )
# return interpolated
def approx_val_from_bins(self, matrice, numeric_matrice, row_label, col_label):
"""
Renvoie une approximation de la valeur à partir des labels binaires (e.g. B5, H1)
en utilisant une interpolation simple basée sur les indices.
Parameters:
matrix_df (pd.DataFrame): Matrice avec les labels binaires en index et colonnes.
row_label (str): Label de la ligne (ex: 'B3').
col_label (str): Label de la colonne (ex: 'H2').
Returns:
float: Valeur approchée si possible, sinon NaN.
"""
# Vérification des labels
if row_label not in matrice.index or col_label not in matrice.columns:
return np.nan
# Index correspondant
row_idx = self.label_to_index.get(row_label)
col_idx = self.label_to_index.get(col_label)
# Approximation directe (aucune interpolation complexe ici, juste une lecture)
return numeric_matrice[row_idx, col_idx]
@property
def protections(self):
return [
{
"method": "CooldownPeriod",
"stop_duration_candles": 12
}
# {
# "method": "MaxDrawdown",
# "lookback_period_candles": self.lookback.value,
# "trade_limit": self.trade_limit.value,
# "stop_duration_candles": self.protection_stop.value,
# "max_allowed_drawdown": self.protection_max_allowed_dd.value,
# "only_per_pair": False
# },
# {
# "method": "StoplossGuard",
# "lookback_period_candles": 24,
# "trade_limit": 4,
# "stop_duration_candles": self.protection_stoploss_stop.value,
# "only_per_pair": False
# },
# {
# "method": "StoplossGuard",
# "lookback_period_candles": 24,
# "trade_limit": 4,
# "stop_duration_candles": 2,
# "only_per_pair": False
# },
# {
# "method": "LowProfitPairs",
# "lookback_period_candles": 6,
# "trade_limit": 2,
# "stop_duration_candles": 60,
# "required_profit": 0.02
# },
# {
# "method": "LowProfitPairs",
# "lookback_period_candles": 24,
# "trade_limit": 4,
# "stop_duration_candles": 2,
# "required_profit": 0.01
# }
]
def conditional_smoothing(self, series, threshold=0.002):
smoothed = [series.iloc[0]]
for val in series.iloc[1:]:
last = smoothed[-1]
if abs(val - last) / last >= threshold:
smoothed.append(val)
else:
smoothed.append(last)
return pd.Series(smoothed, index=series.index)
def smooth_and_derivatives(self, series, window=25, polyorder=3):
series = series.copy()
if series.isna().sum() > 0:
series = series.ffill().bfill() # Si tu veux éviter toute NaN
smooth = self.causal_savgol(series, window=window, polyorder=polyorder)
deriv1 = np.diff(smooth, prepend=smooth[0])
deriv2 = np.diff(deriv1, prepend=deriv1[0])
return pd.Series(smooth, index=series.index), pd.Series(deriv1, index=series.index), pd.Series(deriv2,
index=series.index)
def causal_savgol(self, series, window=25, polyorder=3):
result = []
half_window = window # Fenêtre complète dans le passé
for i in range(len(series)):
if i < half_window:
result.append(np.nan)
continue
window_series = series[i - half_window:i]
if window_series.isna().any():
result.append(np.nan)
continue
coeffs = np.polyfit(range(window), window_series, polyorder)
poly = np.poly1d(coeffs)
result.append(poly(window - 1))
return pd.Series(result, index=series.index)
def get_stake_from_drawdown(self, pct: float, base_stake: float = 100.0, step: float = 0.04, growth: float = 1.15,
max_stake: float = 1000.0) -> float:
"""
Calcule la mise à allouer en fonction du drawdown.
:param pct: Drawdown en pourcentage (ex: -0.12 pour -12%)
:param base_stake: Mise de base (niveau 0)
:param step: Espacement entre paliers (ex: tous les -4%)
:param growth: Facteur de croissance par palier (ex: 1.15 pour +15%)
:param max_stake: Mise maximale à ne pas dépasser
:return: Montant à miser
"""
if pct >= 0:
return base_stake
level = int(abs(pct) / step)
stake = base_stake * (growth ** level)
return min(stake, max_stake)
def compute_adaptive_paliers(self, max_drawdown: float = 0.65, first_steps: list[float] = [0.01, 0.01, 0.015, 0.02],
growth: float = 1.2) -> list[float]:
"""
Génère une liste de drawdowns négatifs avec des paliers plus rapprochés au début.
:param max_drawdown: Drawdown max (ex: 0.65 pour -65%)
:param first_steps: Liste des premiers paliers fixes en % (ex: [0.01, 0.01, 0.015])
:param growth: Facteur multiplicatif pour espacer les paliers suivants
:return: Liste de drawdowns négatifs (croissants)
"""
paliers = []
cumulated = 0.0
# Étapes initiales rapprochées
for step in first_steps:
cumulated += step
paliers.append(round(-cumulated, 4))
# Étapes suivantes plus espacées
step = first_steps[-1]
while cumulated < max_drawdown:
step *= growth
cumulated += step
if cumulated >= max_drawdown:
break
paliers.append(round(-cumulated, 4))
return paliers
# def get_dca_stakes(self,
# max_drawdown: float = 0.65,
# base_stake: float = 100.0,
# first_steps: list[float] = [0.01, 0.01, 0.015, 0.015],
# growth: float = 1.2,
# stake_growth: float = 1.15
# ) -> list[tuple[float, float]]:
# """
# Génère les paliers de drawdown et leurs stakes associés.
#
# :param max_drawdown: Maximum drawdown (ex: 0.65 pour -65%)
# :param base_stake: Mise initiale
# :param first_steps: Paliers de départ (plus resserrés)
# :param growth: Multiplicateur d'espacement des paliers
# :param stake_growth: Croissance multiplicative des mises
# :return: Liste de tuples (palier_pct, stake)
# [(-0.01, 100.0), (-0.02, 115.0), (-0.035, 132.25), (-0.05, 152.09), (-0.068, 174.9),
# (-0.0896, 201.14), (-0.1155, 231.31), (-0.1466, 266.0), (-0.1839, 305.9), (-0.2287, 351.79),
# (-0.2825, 404.56), (-0.347, 465.24), (-0.4244, 535.03), (-0.5173, 615.28), (-0.6287, 707.57)]
# """
# paliers = [
# (-0.01, 100.0), (-0.02, 115.0), (-0.035, 130), (-0.05, 150), (-0.07, 150),
# (-0.10, 150), (-0.15, 150), (-0.20, 150), (-0.25, 150),
# (-0.30, 200), (-0.40, 200),
# (-0.50, 300), (-0.60, 400), (-0.70, 500), (-0.80, 1000)
# ]
#
# # cumulated = 0.0
# # stake = base_stake
# #
# # # Étapes initiales
# # for step in first_steps:
# # cumulated += step
# # paliers.append((round(-cumulated, 4), round(stake, 2)))
# # stake *= stake_growth
# #
# # # Étapes suivantes
# # step = first_steps[-1]
# # while cumulated < max_drawdown:
# # step *= growth
# # cumulated += step
# # if cumulated >= max_drawdown:
# # break
# # paliers.append((round(-cumulated, 4), round(stake, 2)))
# # stake *= stake_growth
#
# return paliers
# def get_active_stake(self, pct: float) -> float:
# """
# Renvoie la mise correspondant au drawdown `pct`.
#
# :param pct: drawdown courant (négatif, ex: -0.043)
# :param paliers: liste de tuples (drawdown, stake)
# :return: stake correspondant
# """
# abs_pct = abs(pct)
# stake = self.paliers[0][1] # stake par défaut
#
# for palier, s in self.paliers:
# if abs_pct >= abs(palier):
# stake = s
# else:
# break
#
# return stake
# def get_palier_index(self, pct):
# """
# Retourne l'index du palier franchi pour un pourcentage de baisse donné (pct).
# On cherche le palier le plus profond atteint (dernier franchi).
# """
# for i in reversed(range(len(self.paliers))):
# seuil, _ = self.paliers[i]
# #print(f"pct={pct} seuil={seuil}")
# if pct <= seuil:
# # print(pct)
# return i
# return None # Aucun palier atteint
# def poly_regression_predictions(self, series: pd.Series, window: int = 20, degree: int = 2, n_future: int = 3) -> pd.DataFrame:
# """
# Renvoie une DataFrame avec `n_future` colonnes contenant les extrapolations des n prochains points
# selon une régression polynomiale ajustée sur les `window` dernières valeurs.
# """
# result = pd.DataFrame(index=series.index)
# x = np.arange(window)
#
# for future_step in range(1, n_future + 1):
# result[f'poly_pred_t+{future_step}'] = np.nan
#
# for i in range(window - 1, len(series)):
# y = series.iloc[i - window + 1 : i + 1].values
#
# if np.any(pd.isna(y)):
# continue
#
# coeffs = np.polyfit(x, y, degree)
# poly = np.poly1d(coeffs)
#
# for future_step in range(1, n_future + 1):
# future_x = window - 1 + future_step # Extrapolation point
# result.loc[series.index[i], f'poly_pred_t+{future_step}'] = poly(future_x)
#
# return result
def polynomial_forecast(self, series: pd.Series, window: int = 20, degree: int = 2, steps=[12, 24, 36]):
"""
Calcule une régression polynomiale sur les `window` dernières valeurs de la série,
puis prédit les `n_future` prochaines valeurs.
:param series: Série pandas (ex: dataframe['close'])
:param window: Nombre de valeurs récentes utilisées pour ajuster le polynôme
:param degree: Degré du polynôme (ex: 2 pour quadratique)
:param n_future: Nombre de valeurs futures à prédire
:return: tuple (poly_function, x_vals, y_pred), où y_pred contient les prédictions futures
"""
if len(series) < window:
raise ValueError("La série est trop courte pour la fenêtre spécifiée.")
recent_y = series.iloc[-window:].values
x = np.arange(window)
coeffs = np.polyfit(x, recent_y, degree)
poly = np.poly1d(coeffs)
x_future = np.arange(window, window + len(steps))
y_future = poly(x_future)
# Affichage de la fonction
# print("Fonction polynomiale trouvée :")
# print(poly)
current = series.iloc[-1]
count = 0
for future_step in steps: # range(1, n_future + 1)
future_x = window - 1 + future_step
prediction = poly(future_x)
# series.loc[series.index[future_x], f'poly_pred_t+{future_step}'] = prediction
# Afficher les prédictions
# print(f"{current} → t+{future_step}: x={future_x}, y={prediction:.2f}")
if prediction > 0: # current:
count += 1
return poly, x_future, y_future, count
# def calculateStats2(self, df, index, target):
# # Nombre de tranches (modifiable)
# n_bins_indice = 11
# n_bins_valeur = 11
#
# # Tranches dynamiques
# # df['indice_tranche'] = pd.qcut(df[f"{index}"], q=n_bins_indice, duplicates='drop')
# # df['valeur_tranche'] = pd.qcut(df[f"{target}"], q=n_bins_valeur, duplicates='drop')
#
# df[f"{index}_bin"], bins_1h = pd.qcut(df[f"{index}"], q=n_bins_indice, labels=self.labels, retbins=True,
# duplicates='drop')
# df[f"{target}_bin"], bins_1d = pd.qcut(df[f"{target}"], q=n_bins_valeur, labels=self.labels, retbins=True,
# duplicates='drop')
# # Affichage formaté pour code Python
# print(f"Bornes des quantiles pour {index} : [{', '.join([f'{b:.4f}' for b in bins_1h])}]")
# print(f"Bornes des quantiles pour {target} : [{', '.join([f'{b:.4f}' for b in bins_1d])}]")
#
# # Tableau croisé (compte)
# tableau = pd.crosstab(df[f"{index}_bin"], df[f"{target}_bin"])
#
# # Facultatif : en pourcentages
# tableau_pct = tableau.div(tableau.sum(axis=1), axis=0) * 100
#
# # Affichage
# print("Répartition brute :")
# print(tableau)
# print("\nRépartition en % par ligne :")
# print(tableau_pct.round(2))
def calculateStats(self, df, index, target):
# Nombre de tranches (modifiable)
n_bins_indice = 11
n_bins_valeur = 11
# Créer les tranches dynamiques
df['indice_tranche'] = pd.qcut(df[index], q=n_bins_indice, duplicates='drop')
df['valeur_tranche'] = pd.qcut(df[target], q=n_bins_valeur, duplicates='drop')
# Créer un tableau croisé avec la moyenne des valeurs
pivot_mean = df.pivot_table(
index='indice_tranche',
columns='valeur_tranche',
values=target, # <-- c'est la colonne qu'on agrège
aggfunc='mean' # <-- on calcule la moyenne
)
# Résultat
print("Moyenne des valeurs par double-tranche :")
print(pivot_mean.round(2))
def should_enter_trade(self, pair: str, last_candle, current_time) -> bool:
limit = 3
# if self.pairs[pair]['count_of_buys'] > 3:
# if last_candle['inversion_basse_1d']:
# if self.pairs[pair]['stop'] == True :
# self.pairs[pair]['stop'] = False
# print(f"start buying {last_candle['sma20_deriv1_1d']} {last_candle['sma20_deriv2_1d']}")
# else:
# if last_candle['inversion_haute_1d']:
# if self.pairs[pair]['stop'] == False:
# self.pairs[pair]['stop'] = True
# print(f"stop buying {last_candle['rsi6_1d']} {last_candle['percent_1d']} {last_candle['sma20_deriv1_1d']} {last_candle['sma20_deriv2_1d']}")
# return False
#
# if self.pairs[pair]['stop']:
# return False
if pair.startswith('BTC'):
return True # BTC toujours autorisé
# Filtrer les paires non-BTC
non_btc_pairs = [p for p in self.pairs if not p.startswith('BTC')]
# Compter les positions actives sur les paires non-BTC
max_nb_trades = 0
total_non_btc = 0
max_pair = ''
limit_amount = 250
max_amount = 0
for p in non_btc_pairs:
max_nb_trades = max(max_nb_trades, self.pairs[p]['count_of_buys'])
max_amount = max(max_amount, self.pairs[p]['total_amount'])
for p in non_btc_pairs:
if (max_nb_trades == self.pairs[p]['count_of_buys'] and max_nb_trades > limit):
# if (max_amount == self.pairs[p]['total_amount'] and max_amount > limit_amount):
max_pair = p
total_non_btc += self.pairs[p]['count_of_buys']
pct_max = self.getPctFirstBuy(pair, last_candle) #self.getPctLastBuy(pair, last_candle)
val = self.getProbaHausseSma5d(last_candle)
if (val < 15):
return False
# if count_decrease == len(non_btc_pairs):
# self.should_enter_trade_count += 1
# char="."
# print(f"should_enter_trade canceled all pairs decreased {'':{char}>{self.should_enter_trade_count}}")
# return False
# if self.pairs[pair]['count_of_buys'] >= 3:
# if last_candle['sma20_deriv1_1d'] < 0 and last_candle['sma5_deriv1_1d'] < 0 and last_candle['sma24_deriv1_1h'] < 0:
# return False
self.should_enter_trade_count = 0
if max_pair != '' :
return max_pair == pair or pct_max < - 0.25
else:
return True
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