# pragma pylint: disable=W0603 """ Edge positioning package """ import logging from typing import Any, Dict import arrow import numpy as np import utils_find_1st as utf1st from pandas import DataFrame import freqtrade.optimize as optimize from freqtrade.optimize.backtesting import BacktestResult from freqtrade.arguments import Arguments from freqtrade.arguments import TimeRange from freqtrade.strategy.interface import SellType from freqtrade.strategy.resolver import IStrategy, StrategyResolver from freqtrade.optimize.backtesting import Backtesting logger = logging.getLogger(__name__) class Edge(): config: Dict = {} _last_updated: int # Timestamp of pairs last updated time _cached_pairs: list = [] # Keeps an array of # [pair, winrate, risk reward ratio, required risk reward, expectancy] _total_capital: float _allowed_risk: float _since_number_of_days: int _timerange: TimeRange def __init__(self, config: Dict[str, Any], exchange=None) -> None: self.config = config self.exchange = exchange self.strategy: IStrategy = StrategyResolver(self.config).strategy self.ticker_interval = self.strategy.ticker_interval self.tickerdata_to_dataframe = self.strategy.tickerdata_to_dataframe self.get_timeframe = Backtesting.get_timeframe self.advise_sell = self.strategy.advise_sell self.advise_buy = self.strategy.advise_buy self.edge_config = self.config.get('edge', {}) self._cached_pairs: list = [] self._total_capital = self.edge_config.get('total_capital_in_stake_currency') self._allowed_risk = self.edge_config.get('allowed_risk') self._since_number_of_days = self.edge_config.get('since_number_of_days', 14) self._last_updated = 0 self._timerange = Arguments.parse_timerange("%s-" % arrow.now().shift( days=-1 * self._since_number_of_days).format('YYYYMMDD')) self.fee = self.exchange.get_fee() def calculate(self) -> bool: pairs = self.config['exchange']['pair_whitelist'] heartbeat = self.edge_config.get('process_throttle_secs') if (self._last_updated > 0) and ( self._last_updated + heartbeat > arrow.utcnow().timestamp): return False data: Dict[str, Any] = {} logger.info('Using stake_currency: %s ...', self.config['stake_currency']) logger.info('Using local backtesting data (using whitelist in given config) ...') data = optimize.load_data( self.config['datadir'], pairs=pairs, ticker_interval=self.ticker_interval, refresh_pairs=True, exchange=self.exchange, timerange=self._timerange ) if not data: logger.critical("No data found. Edge is stopped ...") return False preprocessed = self.tickerdata_to_dataframe(data) # Print timeframe min_date, max_date = self.get_timeframe(preprocessed) logger.info( 'Measuring data from %s up to %s (%s days) ...', min_date.isoformat(), max_date.isoformat(), (max_date - min_date).days ) headers = ['date', 'buy', 'open', 'close', 'sell', 'high', 'low'] stoploss_range_min = float(self.edge_config.get('stoploss_range_min', -0.01)) stoploss_range_max = float(self.edge_config.get('stoploss_range_max', -0.05)) stoploss_range_step = float(self.edge_config.get('stoploss_range_step', -0.001)) stoploss_range = np.arange(stoploss_range_min, stoploss_range_max, stoploss_range_step) trades: list = [] for pair, pair_data in preprocessed.items(): # Sorting dataframe by date and reset index pair_data = pair_data.sort_values(by=['date']) pair_data = pair_data.reset_index(drop=True) ticker_data = self.advise_sell( self.advise_buy(pair_data, {'pair': pair}), {'pair': pair})[headers].copy() trades += self._find_trades_for_stoploss_range(ticker_data, pair, stoploss_range) # Switch List of Trade Dicts (trades) to Dataframe # Fill missing, calculable columns, profit, duration , abs etc. trades_df = DataFrame(trades) if len(trades_df) > 0: # Only post process a frame if it has a record trades_df = self._fill_calculable_fields(trades_df) else: trades_df = DataFrame.from_records(trades_df, columns=BacktestResult._fields) self._cached_pairs = self._process_expectancy(trades_df) self._last_updated = arrow.utcnow().timestamp # Not a nice hack but probably simplest solution: # When backtest load data it loads the delta between disk and exchange # The problem is that exchange consider that recent. # it is but it is incomplete (c.f. _async_get_candle_history) # So it causes get_signal to exit cause incomplete ticker_hist # A patch to that would be update _pairs_last_refresh_time of exchange # so it will download again all pairs # Another solution is to add new data to klines instead of reassigning it: # self.klines[pair].update(data) instead of self.klines[pair] = data in exchange package. # But that means indexing timestamp and having a verification so that # there is no empty range between two timestaps (recently added and last # one) self.exchange._pairs_last_refresh_time = {} return True def stake_amount(self, pair: str) -> str: info = [x for x in self._cached_pairs if x[0] == pair][0] stoploss = info[1] allowed_capital_at_risk = round(self._total_capital * self._allowed_risk, 5) position_size = abs(round((allowed_capital_at_risk / stoploss), 5)) return position_size def stoploss(self, pair: str) -> float: info = [x for x in self._cached_pairs if x[0] == pair][0] return info[1] def filter(self, pairs) -> list: # Filtering pairs acccording to the expectancy filtered_expectancy: list = [] filtered_expectancy = [ x[0] for x in self._cached_pairs if x[5] > float( self.edge_config.get( 'minimum_expectancy', 0.2))] # Only return pairs which are included in "pairs" argument list final = [x for x in filtered_expectancy if x in pairs] return final def _fill_calculable_fields(self, result: DataFrame): """ The result frame contains a number of columns that are calculable from other columns. These are left blank till all rows are added, to be populated in single vector calls. Columns to be populated are: - Profit - trade duration - profit abs :param result Dataframe :return: result Dataframe """ # stake and fees # stake = 0.015 # 0.05% is 0.0005 # fee = 0.001 stake = self.config.get('stake_amount') fee = self.fee open_fee = fee / 2 close_fee = fee / 2 result['trade_duration'] = result['close_time'] - result['open_time'] result['trade_duration'] = result['trade_duration'].map( lambda x: int(x.total_seconds() / 60)) # Spends, Takes, Profit, Absolute Profit # Buy Price result['buy_vol'] = stake / result['open_rate'] # How many target are we buying result['buy_fee'] = stake * open_fee result['buy_spend'] = stake + result['buy_fee'] # How much we're spending # Sell price result['sell_sum'] = result['buy_vol'] * result['close_rate'] result['sell_fee'] = result['sell_sum'] * close_fee result['sell_take'] = result['sell_sum'] - result['sell_fee'] # profit_percent result['profit_percent'] = (result['sell_take'] - result['buy_spend']) / result['buy_spend'] # Absolute profit result['profit_abs'] = result['sell_take'] - result['buy_spend'] return result def _process_expectancy(self, results: DataFrame) -> list: """ This is a temporary version of edge positioning calculation. The function will be eventually moved to a plugin called Edge in order to calculate necessary WR, RRR and other indictaors related to money management periodically (each X minutes) and keep it in a storage. The calulation will be done per pair and per strategy. """ # Removing pairs having less than min_trades_number min_trades_number = self.edge_config.get('min_trade_number', 15) results = results.groupby('pair').filter(lambda x: len(x) > min_trades_number) ################################### # Removing outliers (Only Pumps) from the dataset # The method to detect outliers is to calculate standard deviation # Then every value more than (standard deviation + 2*average) is out (pump) # # Calculating standard deviation of profits std = results[["profit_abs"]].std() # # Calculating average of profits avg = results[["profit_abs"]].mean() # # Removing Pumps if self.edge_config.get('remove_pumps', True): results = results[results.profit_abs < float(avg + 2 * std)] ########################################################################## # Removing trades having a duration more than X minutes (set in config) max_trade_duration = self.edge_config.get('max_trade_duration_minute', 1440) results = results[results.trade_duration < max_trade_duration] ####################################################################### # Win Rate is the number of profitable trades # Divided by number of trades def winrate(x): x = x[x > 0].count() / x.count() return x ############################# # Risk Reward Ratio # 1 / ((loss money / losing trades) / (gained money / winning trades)) def risk_reward_ratio(x): x = abs(1 / ((x[x < 0].sum() / x[x < 0].count()) / (x[x > 0].sum() / x[x > 0].count()))) return x ############################## # Required Risk Reward # (1/(winrate - 1) def required_risk_reward(x): x = (1 / (x[x > 0].count() / x.count()) - 1) return x ############################## # Expectancy # Tells you the interest percentage you should hope # E.x. if expectancy is 0.35, on $1 trade you should expect a target of $1.35 def expectancy(x): average_win = float(x[x > 0].sum() / x[x > 0].count()) average_loss = float(abs(x[x < 0].sum() / x[x < 0].count())) winrate = float(x[x > 0].count() / x.count()) x = ((1 + average_win / average_loss) * winrate) - 1 return x ############################## final = results.groupby(['pair', 'stoploss'])['profit_abs'].\ agg([winrate, risk_reward_ratio, required_risk_reward, expectancy]).\ reset_index().sort_values(by=['expectancy', 'stoploss'], ascending=False)\ .groupby('pair').first().sort_values(by=['expectancy'], ascending=False) # Returning an array of pairs in order of "expectancy" return final.reset_index().values def _find_trades_for_stoploss_range(self, ticker_data, pair, stoploss_range): buy_column = ticker_data['buy'].values sell_column = ticker_data['sell'].values date_column = ticker_data['date'].values ohlc_columns = ticker_data[['open', 'high', 'low', 'close']].values result: list = [] for stoploss in stoploss_range: result += self._detect_stop_and_sell_points( buy_column, sell_column, date_column, ohlc_columns, round(stoploss, 6), pair ) return result def _detect_stop_and_sell_points( self, buy_column, sell_column, date_column, ohlc_columns, stoploss, pair, start_point=0): result: list = [] open_trade_index = utf1st.find_1st(buy_column, 1, utf1st.cmp_equal) # return empty if we don't find trade entry (i.e. buy==1) or # we find a buy but at the of array if open_trade_index == -1 or open_trade_index == len(buy_column) - 1: return [] stop_price_percentage = stoploss + 1 open_price = ohlc_columns[open_trade_index + 1, 0] stop_price = (open_price * stop_price_percentage) # Searching for the index where stoploss is hit stop_index = utf1st.find_1st( ohlc_columns[open_trade_index + 1:, 2], stop_price, utf1st.cmp_smaller) # If we don't find it then we assume stop_index will be far in future (infinite number) if stop_index == -1: stop_index = float('inf') # Searching for the index where sell is hit sell_index = utf1st.find_1st(sell_column[open_trade_index + 1:], 1, utf1st.cmp_equal) # If we don't find it then we assume sell_index will be far in future (infinite number) if sell_index == -1: sell_index = float('inf') # Check if we don't find any stop or sell point (in that case trade remains open) # It is not interesting for Edge to consider it so we simply ignore the trade # And stop iterating there is no more entry if stop_index == sell_index == float('inf'): return [] if stop_index <= sell_index: exit_index = open_trade_index + stop_index + 1 exit_type = SellType.STOP_LOSS exit_price = stop_price elif stop_index > sell_index: exit_index = open_trade_index + sell_index + 1 exit_type = SellType.SELL_SIGNAL exit_price = ohlc_columns[exit_index, 0] trade = {'pair': pair, 'stoploss': stoploss, 'profit_percent': '', 'profit_abs': '', 'open_time': date_column[open_trade_index], 'close_time': date_column[exit_index], 'open_index': start_point + open_trade_index + 1, 'close_index': start_point + exit_index, 'trade_duration': '', 'open_rate': round(open_price, 15), 'close_rate': round(exit_price, 15), 'exit_type': exit_type } result.append(trade) # Calling again the same function recursively but giving # it a view of exit_index till the end of array return result + self._detect_stop_and_sell_points( buy_column[exit_index:], sell_column[exit_index:], date_column[exit_index:], ohlc_columns[exit_index:], stoploss, pair, (start_point + exit_index) )