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Freqtrade/Zeus_11.py
Jérôme Delacotte 914cb9c8e2 Zeus_11 ménage
2025-04-02 23:48:43 +02:00

868 lines
40 KiB
Python
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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
from scipy.special import binom
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
logger = logging.getLogger(__name__)
from tabulate import tabulate
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_11(IStrategy):
levels = [1, 2, 2, 4, 6, 8, 10, 12, 14, 16, 18, 20]
# ROI table:
minimal_roi = {
"0": 0.564,
"567": 0.273,
"2814": 0.12,
"7675": 0
}
# Stoploss:
stoploss = -1 # 0.256
# Custom stoploss
use_custom_stoploss = False
# Buy hypers
timeframe = '5m'
columns_logged = False
# DCA config
position_adjustment_enable = True
plot_config = {
"main_plot": {
"min200": {
"color": "#86c932"
},
"max50": {
"color": "white"
},
"max200": {
"color": "yellow"
},
"bb_lowerband": {
"color": "#da59a6"},
"bb_upperband": {
"color": "#da59a6",
}
},
"subplots": {
"Rsi": {
"rsi": {
"color": "pink"
}
},
"Percent": {
"max_min": {
"color": "#74effc"
}
}
}
}
# 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
trades = list()
max_profit_pairs = {}
profit_b_no_change = BooleanParameter(default=True, space="sell")
profit_b_quick_lost = BooleanParameter(default=True, space="sell")
profit_b_sma5 = BooleanParameter(default=True, space="sell")
profit_b_sma10 = BooleanParameter(default=True, space="sell")
profit_b_sma20 = BooleanParameter(default=True, space="sell")
profit_b_quick_gain = BooleanParameter(default=True, space="sell")
profit_b_quick_gain_3 = BooleanParameter(default=True, space="sell")
profit_b_old_sma10 = BooleanParameter(default=True, space="sell")
profit_b_very_old_sma10 = BooleanParameter(default=True, space="sell")
profit_b_over_rsi = BooleanParameter(default=True, space="sell")
profit_b_short_loss = BooleanParameter(default=True, space="sell")
sell_b_percent = DecimalParameter(0, 0.02, decimals=3, default=0.01, space='sell')
sell_b_percent3 = DecimalParameter(0, 0.02, decimals=3, default=0.01, space='sell')
sell_b_candels = IntParameter(0, 48, default=12, space='sell')
sell_b_too_old_day = IntParameter(0, 10, default=300, space='sell')
sell_b_too_old_percent = DecimalParameter(0, 0.02, decimals=3, default=0.01, space='sell')
sell_b_profit_no_change = DecimalParameter(0, 0.02, decimals=3, default=0.005, space='sell')
sell_b_profit_percent12 = DecimalParameter(0, 0.002, decimals=4, default=0.001, space='sell')
sell_b_RSI = IntParameter(70, 98, default=88, space='sell')
sell_b_RSI2 = IntParameter(70, 98, default=88, space='sell')
sell_b_RSI3 = IntParameter(70, 98, default=80, space='sell')
sell_b_RSI2_percent = DecimalParameter(0, 0.02, decimals=3, default=0.01, space='sell')
# sell_b_expected_profit = DecimalParameter(0, 0.01, decimals=3, default=0.01, space='sell')
profit_h_no_change = BooleanParameter(default=True, space="sell")
profit_h_quick_lost = BooleanParameter(default=True, space="sell")
profit_h_sma5 = BooleanParameter(default=True, space="sell")
profit_h_sma10 = BooleanParameter(default=True, space="sell")
profit_h_sma20 = BooleanParameter(default=True, space="sell")
profit_h_quick_gain = BooleanParameter(default=True, space="sell")
profit_h_quick_gain_3 = BooleanParameter(default=True, space="sell")
profit_h_old_sma10 = BooleanParameter(default=True, space="sell")
profit_h_very_old_sma10 = BooleanParameter(default=True, space="sell")
profit_h_over_rsi = BooleanParameter(default=True, space="sell")
profit_h_short_loss = BooleanParameter(default=True, space="sell")
sell_h_percent = DecimalParameter(0, 0.02, decimals=3, default=0.01, space='sell')
sell_h_percent3 = DecimalParameter(0, 0.02, decimals=3, default=0.01, space='sell')
sell_h_candels = IntParameter(0, 48, default=12, space='sell')
sell_h_too_old_day = IntParameter(0, 10, default=300, space='sell')
sell_h_too_old_percent = DecimalParameter(0, 0.02, decimals=3, default=0.01, space='sell')
sell_h_profit_no_change = DecimalParameter(0, 0.02, decimals=3, default=0.005, space='sell')
sell_h_profit_percent12 = DecimalParameter(0, 0.002, decimals=4, default=0.001, space='sell')
sell_h_RSI = IntParameter(70, 98, default=88, space='sell')
sell_h_RSI2 = IntParameter(70, 98, default=88, space='sell')
sell_h_RSI3 = IntParameter(70, 98, default=80, space='sell')
sell_h_RSI2_percent = DecimalParameter(0, 0.02, decimals=3, default=0.01, space='sell')
protection_percent_buy_lost = IntParameter(1, 10, default=5, space='protection')
# protection_nb_buy_lost = IntParameter(1, 2, default=2, space='protection')
protection_fibo = IntParameter(1, 10, default=2, space='protection')
# trailing stoploss hyperopt parameters
# hard stoploss profit
sell_allow_decrease = DecimalParameter(0.005, 0.02, default=0.2, decimals=2, space='sell', optimize=True, load=True)
pairs = {
pair: {
"first_buy": 0,
"last_max": 0,
"trade_info": {},
"max_touch": 0.0,
"last_sell": 0.0,
"last_buy": 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
}
for pair in ["BTC/USDC", "ETH/USDC", "DOGE/USDC", "XRP/USDC", "SOL/USDC",
"BTC/USDT", "ETH/USDT", "DOGE/USDT", "XRP/USDT", "SOL/USDT"]
}
def min_max_scaling(self, series: pd.Series) -> pd.Series:
"""Normaliser les données en les ramenant entre 0 et 100."""
return 100 * (series - series.min()) / (series.max() - series.min())
def z_score_scaling(self, series: pd.Series) -> pd.Series:
"""Normaliser les données en utilisant Z-Score Scaling."""
return (series - series.mean()) / series.std()
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:
# count_buys = 0
# trade = self.getTrade(pair)
# if trade:
# filled_buys = trade.select_filled_orders('buy')
# count_buys = len(filled_buys)
dataframe, _ = self.dp.get_analyzed_dataframe(pair, self.timeframe)
last_candle = dataframe.iloc[-1].squeeze()
# last_candle_12 = dataframe.iloc[-13].squeeze()
# allow_to_buy = True #(not self.stop_all) #& (not self.all_down)
allow_to_buy = True # (rate <= float(limit)) | (entry_tag == 'force_entry')
self.trades = list()
dispo = round(self.wallets.get_available_stake_amount())
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
print(
f"|{'-' * 18}+{'-' * 12}+{'-' * 12}+{'-' * 20}+{'-' * 14}+{'-' * 8}+{'-' * 10}+{'-' * 7}+{'-' * 13}+{'-' * 14}+{'-' * 14}+{'-' * 7}+{'-' * 12}|"
)
stake_amount = self.adjust_stake_amount(pair, last_candle)
self.log_trade(
last_candle=last_candle,
date=current_time,
action="START BUY",
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)
if allow_to_sell:
self.pairs[pair]['last_count_of_buys'] = 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.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",
pair=pair,
trade_type=exit_reason,
rate=last_candle['close'],
dispo=dispo,
profit=round(trade.calc_profit(rate, amount), 2)
)
self.pairs[pair]['max_touch'] = 0
self.pairs[pair]['last_buy'] = 0
# else:
# print('Cancel Sell ' + exit_reason + ' ' + str(current_time) + ' ' + pair)
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()
before_last_candle = dataframe.iloc[-2].squeeze()
count_of_buys = trade.nr_of_successful_entries
max_touch_before = self.pairs[pair]['max_touch']
self.pairs[pair]['last_max'] = max(last_candle['haclose'], self.pairs[pair]['last_max'])
last_lost = (last_candle['close'] - max_touch_before) / max_touch_before
count_of_buys = trade.nr_of_successful_entries
self.pairs[pair]['count_of_buys'] = count_of_buys
self.pairs[pair]['current_profit'] = current_profit
expected_profit = self.expectedProfit(pair, last_candle)
if (last_candle['percent3'] < 0.0) & (current_profit > last_candle['min_max200'] / 3):
self.trades = list()
return 'min_max200_' + str(count_of_buys)
if (last_candle['percent12'] <= -0.01) & (current_profit >= expected_profit):
self.trades = list()
return 'profit_' + str(count_of_buys)
if (current_profit >= expected_profit) & (last_candle['percent'] < 0.0) \
and ((last_candle['rsi'] >= 75) or before_last_candle['rsi'] >= 75):
self.trades = list()
return 'rsi_' + str(count_of_buys)
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
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 % 30 == 0:
# print(
# f"|{'-' * 18}+{'-' * 12}+{'-' * 12}+{'-' * 20}+{'-' * 14}+{'-' * 8}+{'-' * 10}+{'-' * 7}+{'-' * 13}+{'-' * 14}+{'-' * 14}+{'-' * 7}+{'-' * 12}|"
# )
print(
f"| {'Date':<16} | {'Action':<10} | {'Pair':<10} | {'Trade Type':<18} | {'Rate':>12} | {'Dispo':>6} | {'Profit':>8} | {'Pct':>5} | {'max_touch':>11} | {'last_lost':>12} | {'last_max':>12} | {'Buys':>5} | {'Stake':>10} |"
)
print(
f"|{'-' * 18}+{'-' * 12}+{'-' * 12}+{'-' * 20}+{'-' * 14}+{'-' * 8}+{'-' * 10}+{'-' * 7}+{'-' * 13}+{'-' * 14}+{'-' * 14}+{'-' * 7}+{'-' * 12}|"
)
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['haclose'] - self.pairs[pair]['max_touch']) / self.pairs[pair]['max_touch'], 3)
max_touch = '' #round(last_candle['max12_1d'], 1) #round(self.pairs[pair]['max_touch'], 1)
pct_max = round((last_candle['close'] - self.pairs[pair]['first_buy']) / self.pairs[pair]['first_buy'], 3) # round(100 * self.pairs[pair]['current_profit'], 1)
if trade_type is not None:
trade_type = trade_type \
+ " " + str(round(100 * last_candle['sma5_pct_1d'], 0))
# + " " + str(round(last_candle['sma5_diff_1h'], 1))
print(
f"| {date:<16} | {action:<10} | {pair:<10} | {trade_type or '-':<18} | {rate or '-':>12} | {dispo or '-':>6} | {profit or '-':>8} | {pct_max or '-':>5} | {max_touch or '-':>11} | {last_lost or '-':>12} | {round(self.pairs[pair]['last_max'], 2) or '-':>12} | {buys or '-':>5} | {stake or '-':>10} |"
)
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['close_02'] = dataframe['haclose'] * 1.02
dataframe['pct_change'] = dataframe['close'].pct_change(5)
dataframe['min'] = talib.MIN(dataframe['close'], timeperiod=200)
dataframe['min12'] = talib.MIN(dataframe['close'], timeperiod=12)
dataframe['min50'] = talib.MIN(dataframe['close'], timeperiod=50)
dataframe['min200'] = talib.MIN(dataframe['close'], timeperiod=200)
dataframe['max50'] = talib.MAX(dataframe['close'], timeperiod=50)
dataframe['min_max50'] = (dataframe['max50'] - dataframe['min50']) / dataframe['min50']
dataframe['max200'] = talib.MAX(dataframe['close'], timeperiod=200)
dataframe['min_max200'] = (dataframe['max200'] - dataframe['min200']) / dataframe['min200']
dataframe['max200_diff'] = (dataframe['max200'] - dataframe['close']) / dataframe['close']
dataframe['max50_diff'] = (dataframe['max50'] - dataframe['close']) / dataframe['close']
dataframe['sma5'] = talib.SMA(dataframe, timeperiod=5)
dataframe['sma10'] = talib.SMA(dataframe, timeperiod=10)
dataframe['sma20'] = talib.SMA(dataframe, timeperiod=20)
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["percent24"] = (dataframe["close"] - dataframe["open"].shift(24)) / dataframe["open"].shift(24)
dataframe["percent48"] = (dataframe["close"] - dataframe["open"].shift(48)) / dataframe["open"].shift(48)
# print(metadata['pair'])
dataframe['rsi'] = talib.RSI(dataframe['close'], length=14)
# 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"])
)
# Normalization
dataframe['average_line'] = dataframe['close'].mean()
dataframe['average_line_50'] = talib.MIDPOINT(dataframe['close'], timeperiod=50)
dataframe['average_line_288'] = talib.MIDPOINT(dataframe['close'], timeperiod=288)
# Sort the close prices to find the 4 lowest values
sorted_close_prices = dataframe['close'].tail(576).sort_values()
lowest_4 = sorted_close_prices.head(20)
dataframe['lowest_4_average'] = lowest_4.mean()
# Propagate this mean value across the entire dataframe
# dataframe['lowest_4_average'] = dataframe['lowest_4_average'].iloc[0]
# # Sort the close prices to find the 4 highest values
sorted_close_prices = dataframe['close'].tail(288).sort_values(ascending=False)
highest_4 = sorted_close_prices.head(20)
# # Calculate the mean of the 4 highest values
dataframe['highest_4_average'] = highest_4.mean()
# # Propagate this mean value across the entire dataframe
# dataframe['highest_4_average'] = dataframe['highest_4_average'].iloc[0]
# dataframe['pct_average'] = (dataframe['highest_4_average'] - dataframe['close']) / dataframe['lowest_4_average']
# dataframe['highest_4_average_1'] = dataframe['highest_4_average'] * 0.99
# dataframe['highest_4_average_2'] = dataframe['highest_4_average'] * 0.98
# dataframe['highest_4_average_3'] = dataframe['highest_4_average'] * 0.97
# dataframe['highest_4_average_4'] = dataframe['highest_4_average'] * 0.96
# dataframe['highest_4_average_5'] = dataframe['highest_4_average'] * 0.95
# Compter les baisses consécutives
dataframe['down'] = dataframe['hapercent'] <= 0.001
dataframe['up'] = dataframe['hapercent'] >= -0.001
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)
dataframe['down_tag'] = (dataframe['down_count'] < -7)
dataframe['up_tag'] = (dataframe['up_count'] > 7)
# Créer une colonne vide
dataframe['down_pct'] = self.calculateUpDownPct(dataframe, 'down_count')
dataframe['up_pct'] = self.calculateUpDownPct(dataframe, 'up_count')
# Normaliser les données de 'close'
# normalized_close = self.min_max_scaling(dataframe['close'])
################### INFORMATIVE 1h
# informative = self.dp.get_pair_dataframe(pair=metadata['pair'], timeframe="1h")
# x_percent = 0.01
# n_hours = 6
# n_candles = n_hours * 60 # metadata["timeframe"] # Convertir en bougies
#
# informative["max_profit"] = dataframe["informative"].rolling(n_candles).max()
# informative["profit_hit"] = dataframe["informative"] >= informative["close"] * (1 + x_percent)
#
# 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['sma5'] = talib.SMA(informative, timeperiod=5)
informative['sma5_pct'] = 100 * (informative['sma5'] - informative['sma5'].shift(1)) / informative['sma5']
sorted_close_prices = informative['close'].tail(365).sort_values()
lowest_4 = sorted_close_prices.head(4)
informative['lowest_4'] = lowest_4.mean()
sorted_close_prices = informative['close'].tail(365).sort_values(ascending=False)
highest_4 = sorted_close_prices.head(4)
informative['highest_4'] = highest_4.mean()
last_14_days = informative.tail(14)
# Récupérer le minimum et le maximum de la colonne 'close' des 14 derniers jours
min_14_days = last_14_days['close'].min()
max_14_days = last_14_days['close'].max()
informative['lowest'] = min_14_days
informative['highest'] = max_14_days
informative['pct_min_max'] = (max_14_days - min_14_days) / min_14_days
informative['mid_min_max'] = min_14_days + (max_14_days - min_14_days) / 2
informative['middle'] = informative['lowest_4'] + (informative['highest_4'] - informative['lowest_4']) / 2
informative['mid_min_max_0.98'] = informative['mid_min_max'] * 0.98
dataframe = merge_informative_pair(dataframe, informative, self.timeframe, "1d", ffill=True)
dataframe['count_buys'] = 0
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['amount'] = 0
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
print(trade)
filled_buys = trade.select_filled_orders('buy')
dataframe['count_buys'] = len(filled_buys)
count = 0
amount = 0
for buy in filled_buys:
if count == 0:
dataframe['first_price'] = 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
print(buy)
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
print(f"amount= {amount}")
# # trades = Trade.get_trades([Trade.is_open is False]).all()
# trades = Trade.get_trades_proxy(is_open=False, pair=metadata['pair'])
# if trades:
# trade = trades[-1]
# print('closed trade pair is : ')
# print(trade)
# dataframe['expected_profit'] = (1 + self.expectedProfit(pair, dataframe.iloc[-1])) * dataframe[
# 'last_price']
# dataframe['lbp'] = dataframe['last_price']
# dataframe['lbp_3'] = dataframe['lbp'] * 0.97 # 3
# dataframe['lbp_6'] = dataframe['lbp'] * 0.94 # 6
# dataframe['lbp_9'] = dataframe['lbp'] * 0.90 # 10
# dataframe['lbp_12'] = dataframe['lbp'] * 0.85 # 15
# dataframe['lbp_20'] = dataframe['lbp'] * 0.8 # 20
# dataframe['fbp'] = trade.open_rate
# # else:
# # last_trade = self.get_trades(pair=pair).order_by('-close_date').first()
# # filled_buys = last_trade.select_filled_orders('buy')
# # print(last_trade)
# # for buy in filled_buys:
# # print(filled_buys)
#dataframe['buy_level'] = dataframe['lowest_4_average'] * (1 - self.levels[count_buys] / 100)
dataframe['buy_level'] = dataframe['max50'] * 0.99 #(1 - self.levels[count_buys] / 100)
# ----------------------------------------------------------
# Calcul de la variation entre deux bougies successives
dataframe['price_change'] = dataframe['close'].diff()
# Marquer les bougies en baisse
dataframe['is_down'] = dataframe['price_change'] < 0
# Identifier les blocs consécutifs de baisses
# dataframe['drop_id'] = (dataframe['is_down'] != dataframe['is_down'].shift(1)).cumsum()
dataframe['drop_id'] = np.where(dataframe['is_down'],
(dataframe['is_down'] != dataframe['is_down'].shift(12)).cumsum(), np.nan)
# Identifier uniquement les blocs de baisse
dataframe['drop_id'] = dataframe['drop_id'].where(dataframe['is_down'])
# # Grouper par les chutes détectées
# drop_info = dataframe.groupby('drop_id').agg(
# start=('close', 'first'), # Prix au début de la chute
# end=('close', 'last'), # Prix à la fin de la chute
# start_index=('close', 'idxmin'), # Début de la chute (index)
# end_index=('close', 'idxmax'), # Fin de la chute (index)
# )
#
# # Calcul de l'ampleur de la chute en %
# drop_info['drop_amplitude_pct'] = ((drop_info['end'] - drop_info['start']) / drop_info['start']) * 100
# # Filtrer les chutes avec une amplitude supérieure à 3%
# drop_info = drop_info[drop_info['drop_amplitude_pct'] < -3]
# **************
# Identifier le prix de début et de fin de chaque chute
drop_stats = dataframe.groupby('drop_id').agg(
start_price=('close', 'first'), # Prix au début de la chute
end_price=('close', 'last'), # Prix à la fin de la chute
)
return dataframe
def getOpenTrades(self):
# if len(self.trades) == 0:
print('search open trades')
self.trades = Trade.get_open_trades()
return self.trades
def populate_buy_trend(self, dataframe: DataFrame, metadata: dict) -> DataFrame:
pair = metadata['pair']
#expected_profit = self.expectedProfit(pair, dataframe.iloc[-1])
#last_candle = dataframe.iloc[-1].squeeze()
# print("---------------" + pair + "----------------")
# print('adjust stake amount ' + str(self.adjust_stake_amount(pair, dataframe.iloc[-1])))
# # print('adjust exit price ' + str(self.adjust_exit_price(dataframe.iloc[-1])))
# print('calcul expected_profit ' + str(expected_profit))
# buy_level = dataframe['buy_level'] # self.get_buy_level(pair, dataframe)
dataframe.loc[
(
(dataframe['down_count'].shift(1) < - 6)
& (dataframe['down_count'] == 0)
& (dataframe['down_pct'].shift(1) <= -0.5)
), ['enter_long', 'enter_tag']] = (1, 'buy_hapercent')
dataframe['test'] = np.where(dataframe['enter_long'] == 1, dataframe['close'] * 1.01, np.nan)
return dataframe
def populate_sell_trend(self, dataframe: DataFrame, metadata: dict) -> DataFrame:
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:
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()
# prépare les données
count_of_buys = trade.nr_of_successful_entries
current_time = current_time.astimezone(timezone.utc)
open_date = trade.open_date.astimezone(timezone.utc)
dispo = round(self.wallets.get_available_stake_amount())
hours = (current_time - trade.date_last_filled_utc).total_seconds() / 3600.0
if (len(dataframe) < 1):
return None
pair = trade.pair
if pair not in ('BTC/USDC', 'XRP/USDC', 'BTC/USDT', 'XRP/USDT'):
return None
max_buys = 20
filled_buys = trade.select_filled_orders('buy')
count_of_buys = len(filled_buys)
if count_of_buys >= max_buys:
return None
# if 'buy' in last_candle:
# condition = (last_candle['buy'] == 1)
# else:
# condition = False
# self.protection_nb_buy_lost.value
limit = last_candle['limit']
stake_amount = self.config['stake_amount'] + 50 * self.fibo[count_of_buys]
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
pct_max = round((last_candle['close'] - self.pairs[trade.pair]['last_buy']) / self.pairs[trade.pair]['last_buy'], 3)
# if (days_since_open > count_of_buys) & (0 < count_of_buys <= max_buys) & (current_rate <= limit) & (last_candle['enter_long'] == 1):
if ((last_candle['enter_long'] == 1) or last_candle['percent48'] < - 0.03) \
and (pct_max < -0.012 - (count_of_buys * 0.001)):
try:
# This then calculates current safety order size
# stake_amount = stake_amount * pow(1.5, count_of_buys)
# print(
# f"Adjust {current_time} price={trade.pair} rate={current_rate:.4f} buys={count_of_buys} limit={limit:.4f} stake={stake_amount:.4f}")
self.log_trade(
last_candle=last_candle,
date=current_time,
action="Loss -",
dispo=dispo,
pair=trade.pair,
rate=current_rate,
trade_type=last_candle['enter_tag'],
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 adjust_stake_amount(self, pair: str, dataframe: DataFrame):
# Calculer le minimum des 14 derniers jours
current_price = dataframe['close']
# trade = self.getTrade(pair)
# if trade:
# current_price = trade.open_rate
base_stake_amount = self.config['stake_amount'] #.get('stake_amount', 50) # Montant de base configuré
# Calculer le max des 14 derniers jours
min_14_days_4 = dataframe['lowest_4_1d']
max_14_days_4 = dataframe['highest_4_1d']
percent_4 = 1 - (current_price - min_14_days_4) / (max_14_days_4 - min_14_days_4)
factor_4 = 1 / ((current_price - min_14_days_4) / (max_14_days_4 - min_14_days_4))
max_min_4 = max_14_days_4 / min_14_days_4
# min_14_days = dataframe['lowest_1d']
# max_14_days = dataframe['highest_1d']
# percent = 1 - (current_price - min_14_days) / (max_14_days - min_14_days)
# factor = 1 / ((current_price - min_14_days) / (max_14_days - min_14_days))
# max_min = max_14_days / min_14_days
# Stack amount ajusté price=2473.47 min_max=0.15058074985054215 percent=0.8379141364642171 amount=20.0
adjusted_stake_amount = max(base_stake_amount, min(100, base_stake_amount * percent_4))
# if pair in ('BTC/USDT', 'ETH/USDT'):
# if percent_4 > 0.5:
# adjusted_stake_amount = 300
# adjusted_stake_amount_2 = max(base_stake_amount / 2.5, min(75, base_stake_amount * percent))
# print(
# f"Stack amount ajusté price={current_price} max_min={max_min_4:.4f} min_14={min_14_days_4:.4f} max_14={max_14_days_4:.4f} factor={factor_4:.4f} percent={percent_4:.4f} amount={adjusted_stake_amount:.4f}")
# print(f"Stack amount ajusté price={current_price} max_min={max_min:.4f} min_14={min_14_days:.4f} max_14={max_14_days:.4f} factor={factor:.4f} percent={percent:.4f} amount={adjusted_stake_amount_2:.4f}")
return adjusted_stake_amount
# def adjust_exit_price(self, dataframe: DataFrame):
# # Calculer le max des 14 derniers jours
# min_14_days = dataframe['lowest_1d']
# max_14_days = dataframe['highest_1d']
# entry_price = dataframe['fbp']
# current_price = dataframe['close']
# percent = 0.5 * (max_14_days - min_14_days) / min_14_days
# exit_price = (1 + percent) * entry_price
#
# print(f"Exit price ajusté price={current_price:.4f} max_14={max_14_days:.4f} exit_price={exit_price:.4f}")
#
# return exit_price
# def adjust_stoploss(self, pair: str, trade: 'Trade', current_time: datetime,
# current_rate: float, current_profit: float, **kwargs) -> float:
# dataframe, _ = self.dp.get_analyzed_dataframe(trade.pair, self.timeframe)
# # print(dataframe)
# last_candle = dataframe.iloc[-1].squeeze()
#
# # Utiliser l'ATR pour ajuster le stoploss
# atr_stoploss = current_rate - (last_candle['atr'] * 1.5) # Stoploss à 1.5x l'ATR
#
# # Retourner le stoploss dynamique en pourcentage du prix actuel
# return (atr_stoploss / current_rate) - 1
def expectedProfit(self, pair: str, last_candle):
current_price = last_candle['last_price'] # dataframe['close']
# trade = self.getTrade(pair)
# if trade:
# current_price = trade.open_rate
# Calculer le max des 14 derniers jours
min_14_days = last_candle['lowest_1d']
max_14_days = last_candle['highest_1d']
percent = (max_14_days - current_price) / (min_14_days)
min_max = last_candle['pct_min_max_1d'] # (max_14_days - min_14_days) / min_14_days
expected_profit = min(0.1, max(0.01, last_candle['min_max200'] * 0.5 + self.pairs[pair]['count_of_buys'] * 0.0005))
return expected_profit
# def adjust_exit_price(self, dataframe: DataFrame):
# # Calculer le max des 14 derniers jours
# min_14_days = dataframe['lowest_1d']
# max_14_days = dataframe['highest_1d']
# entry_price = dataframe['fbp']
# current_price = dataframe['close']
# percent = 0.5 * (max_14_days - min_14_days) / min_14_days
# exit_price = (1 + percent) * entry_price
#
# print(f"Exit price ajusté price={current_price} max_14={max_14_days} exit_price={exit_price}")
#
# return exit_price
# def adjust_entry_price(self, dataframe: DataFrame):
# # Calculer le max des 14 derniers jours
# min_14_days = dataframe['lowest_1d']
# max_14_days = dataframe['highest_1d']
# current_price = dataframe['close']
# percent = 0.5 * (max_14_days - min_14_days) / min_14_days
# entry_price = (1 + percent) * entry_price
#
# print(f"Entry price ajusté price={current_price} max_14={max_14_days} exit_price={entry_price}")
#
# return entry_price
# def adjust_stake_amount(self, dataframe: DataFrame):
# # Calculer le minimum des 14 derniers jours
# middle = dataframe['middle_1d']
#
# # Récupérer la dernière cotation actuelle (peut être le dernier point de la série)
# current_price = dataframe['close']
#
# # Calculer l'écart entre la cotation actuelle et le minimum des 14 derniers jours
# difference = middle - current_price
# # Ajuster la stake_amount en fonction de l'écart
# # Par exemple, augmenter la stake_amount proportionnellement à l'écart
# base_stake_amount = self.config.get('stake_amount', 100) # Montant de base configuré
#
# multiplier = 1 - (difference / current_price) # Exemple de logique d'ajustement
#
# adjusted_stake_amount = max(base_stake_amount / 2.5, base_stake_amount * multiplier)
#
# # difference = 346.07000000000016
# # price = 2641.75
# # min_14 = 2295.68
# # amount = 56.5500141951358
#
# print(f"Stack amount ajusté difference={difference} price={current_price} middle={middle} multiplier={multiplier} amount={adjusted_stake_amount}")
#
# return adjusted_stake_amount
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
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