1201 lines
50 KiB
Python
1201 lines
50 KiB
Python
import copy
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import datetime
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import logging
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import shutil
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import sqlite3
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from pathlib import Path
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from typing import Any, Dict, List, Optional, Tuple
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import numpy as np
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import numpy.typing as npt
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import pandas as pd
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from pandas import DataFrame
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from sklearn import linear_model
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from sklearn.cluster import DBSCAN
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from sklearn.metrics.pairwise import pairwise_distances
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from sklearn.model_selection import train_test_split
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from sklearn.neighbors import NearestNeighbors
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from freqtrade.configuration import TimeRange
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from freqtrade.data.dataprovider import DataProvider
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from freqtrade.data.history.history_utils import refresh_backtest_ohlcv_data
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from freqtrade.exceptions import OperationalException
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from freqtrade.exchange import timeframe_to_seconds
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from freqtrade.strategy.interface import IStrategy
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SECONDS_IN_DAY = 86400
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SECONDS_IN_HOUR = 3600
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logger = logging.getLogger(__name__)
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class FreqaiDataKitchen:
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"""
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Class designed to analyze data for a single pair. Employed by the IFreqaiModel class.
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Functionalities include holding, saving, loading, and analyzing the data.
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Record of contribution:
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FreqAI was developed by a group of individuals who all contributed specific skillsets to the
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project.
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Conception and software development:
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Robert Caulk @robcaulk
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Theoretical brainstorming:
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Elin Törnquist @th0rntwig
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Code review, software architecture brainstorming:
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@xmatthias
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Beta testing and bug reporting:
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@bloodhunter4rc, Salah Lamkadem @ikonx, @ken11o2, @longyu, @paranoidandy, @smidelis, @smarm
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Juha Nykänen @suikula, Wagner Costa @wagnercosta
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"""
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def __init__(
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self,
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config: Dict[str, Any],
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live: bool = False,
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pair: str = "",
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):
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self.data: Dict[str, Any] = {}
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self.data_dictionary: Dict[str, DataFrame] = {}
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self.config = config
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self.freqai_config: Dict[str, Any] = config["freqai"]
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self.full_df: DataFrame = DataFrame()
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self.append_df: DataFrame = DataFrame()
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self.data_path = Path()
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self.label_list: List = []
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self.training_features_list: List = []
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self.model_filename: str = ""
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self.live = live
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self.pair = pair
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self.svm_model: linear_model.SGDOneClassSVM = None
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self.keras: bool = self.freqai_config.get("keras", False)
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self.set_all_pairs()
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if not self.live:
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if not self.config["timerange"]:
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raise OperationalException(
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'Please pass --timerange if you intend to use FreqAI for backtesting.')
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self.full_timerange = self.create_fulltimerange(
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self.config["timerange"], self.freqai_config.get("train_period_days", 0)
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)
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(self.training_timeranges, self.backtesting_timeranges) = self.split_timerange(
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self.full_timerange,
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config["freqai"]["train_period_days"],
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config["freqai"]["backtest_period_days"],
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)
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self.database_path: Optional[Path] = None
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if self.live:
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db_url = self.config.get('db_url', None)
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self.database_path = Path(db_url)
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self.database_name = Path(*self.database_path.parts[1:])
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self.trade_database_df: DataFrame = pd.DataFrame()
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self.data['extra_returns_per_train'] = self.freqai_config.get('extra_returns_per_train', {})
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self.thread_count = self.freqai_config.get("data_kitchen_thread_count", -1)
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self.train_dates: DataFrame = pd.DataFrame()
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def set_paths(
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self,
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pair: str,
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trained_timestamp: int = None,
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) -> None:
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"""
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Set the paths to the data for the present coin/botloop
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:params:
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metadata: dict = strategy furnished pair metadata
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trained_timestamp: int = timestamp of most recent training
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"""
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self.full_path = Path(
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self.config["user_data_dir"] / "models" / str(self.freqai_config.get("identifier"))
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)
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self.data_path = Path(
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self.full_path
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/ f"sub-train-{pair.split('/')[0]}_{trained_timestamp}"
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)
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return
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def make_train_test_datasets(
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self, filtered_dataframe: DataFrame, labels: DataFrame
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) -> Dict[Any, Any]:
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"""
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Given the dataframe for the full history for training, split the data into
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training and test data according to user specified parameters in configuration
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file.
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:filtered_dataframe: cleaned dataframe ready to be split.
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:labels: cleaned labels ready to be split.
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"""
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feat_dict = self.freqai_config["feature_parameters"]
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weights: npt.ArrayLike
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if feat_dict.get("weight_factor", 0) > 0:
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weights = self.set_weights_higher_recent(len(filtered_dataframe))
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else:
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weights = np.ones(len(filtered_dataframe))
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if feat_dict.get("stratify_training_data", 0) > 0:
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stratification = np.zeros(len(filtered_dataframe))
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for i in range(1, len(stratification)):
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if i % feat_dict.get("stratify_training_data", 0) == 0:
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stratification[i] = 1
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else:
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stratification = None
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if self.freqai_config.get('data_split_parameters', {}).get('test_size', 0.1) != 0:
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(
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train_features,
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test_features,
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train_labels,
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test_labels,
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train_weights,
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test_weights,
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) = train_test_split(
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filtered_dataframe[: filtered_dataframe.shape[0]],
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labels,
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weights,
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stratify=stratification,
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**self.config["freqai"]["data_split_parameters"],
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)
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else:
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test_labels = np.zeros(2)
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test_features = pd.DataFrame()
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test_weights = np.zeros(2)
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train_features = filtered_dataframe
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train_labels = labels
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train_weights = weights
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return self.build_data_dictionary(
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train_features, test_features, train_labels, test_labels, train_weights, test_weights
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)
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def filter_features(
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self,
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unfiltered_dataframe: DataFrame,
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training_feature_list: List,
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label_list: List = list(),
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training_filter: bool = True,
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) -> Tuple[DataFrame, DataFrame]:
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"""
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Filter the unfiltered dataframe to extract the user requested features/labels and properly
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remove all NaNs. Any row with a NaN is removed from training dataset or replaced with
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0s in the prediction dataset. However, prediction dataset do_predict will reflect any
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row that had a NaN and will shield user from that prediction.
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:params:
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:unfiltered_dataframe: the full dataframe for the present training period
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:training_feature_list: list, the training feature list constructed by
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self.build_feature_list() according to user specified parameters in the configuration file.
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:labels: the labels for the dataset
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:training_filter: boolean which lets the function know if it is training data or
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prediction data to be filtered.
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:returns:
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:filtered_dataframe: dataframe cleaned of NaNs and only containing the user
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requested feature set.
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:labels: labels cleaned of NaNs.
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"""
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filtered_dataframe = unfiltered_dataframe.filter(training_feature_list, axis=1)
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filtered_dataframe = filtered_dataframe.replace([np.inf, -np.inf], np.nan)
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drop_index = pd.isnull(filtered_dataframe).any(1) # get the rows that have NaNs,
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drop_index = drop_index.replace(True, 1).replace(False, 0) # pep8 requirement.
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if (training_filter):
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# we don't care about total row number (total no. datapoints) in training, we only care
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# about removing any row with NaNs
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# if labels has multiple columns (user wants to train multiple modelEs), we detect here
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labels = unfiltered_dataframe.filter(label_list, axis=1)
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drop_index_labels = pd.isnull(labels).any(1)
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drop_index_labels = drop_index_labels.replace(True, 1).replace(False, 0)
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dates = unfiltered_dataframe.filter('date', axis=1)
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filtered_dataframe = filtered_dataframe[
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(drop_index == 0) & (drop_index_labels == 0)
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] # dropping values
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labels = labels[
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(drop_index == 0) & (drop_index_labels == 0)
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] # assuming the labels depend entirely on the dataframe here.
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self.train_dates = dates[
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(drop_index == 0) & (drop_index_labels == 0)
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]
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logger.info(
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f"dropped {len(unfiltered_dataframe) - len(filtered_dataframe)} training points"
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f" due to NaNs in populated dataset {len(unfiltered_dataframe)}."
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)
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if (1 - len(filtered_dataframe) / len(unfiltered_dataframe)) > 0.1 and self.live:
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worst_indicator = str(unfiltered_dataframe.count().idxmin())
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logger.warning(
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f" {(1 - len(filtered_dataframe)/len(unfiltered_dataframe)) * 100:.0f} percent "
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" of training data dropped due to NaNs, model may perform inconsistent "
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f"with expectations. Verify {worst_indicator}"
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)
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self.data["filter_drop_index_training"] = drop_index
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else:
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# we are backtesting so we need to preserve row number to send back to strategy,
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# so now we use do_predict to avoid any prediction based on a NaN
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drop_index = pd.isnull(filtered_dataframe).any(1)
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self.data["filter_drop_index_prediction"] = drop_index
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filtered_dataframe.fillna(0, inplace=True)
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# replacing all NaNs with zeros to avoid issues in 'prediction', but any prediction
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# that was based on a single NaN is ultimately protected from buys with do_predict
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drop_index = ~drop_index
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self.do_predict = np.array(drop_index.replace(True, 1).replace(False, 0))
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if (len(self.do_predict) - self.do_predict.sum()) > 0:
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logger.info(
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"dropped %s of %s prediction data points due to NaNs.",
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len(self.do_predict) - self.do_predict.sum(),
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len(filtered_dataframe),
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)
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labels = []
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return filtered_dataframe, labels
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def build_data_dictionary(
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self,
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train_df: DataFrame,
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test_df: DataFrame,
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train_labels: DataFrame,
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test_labels: DataFrame,
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train_weights: Any,
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test_weights: Any,
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) -> Dict:
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self.data_dictionary = {
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"train_features": train_df,
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"test_features": test_df,
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"train_labels": train_labels,
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"test_labels": test_labels,
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"train_weights": train_weights,
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"test_weights": test_weights,
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"train_dates": self.train_dates
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}
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return self.data_dictionary
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def normalize_data(self, data_dictionary: Dict) -> Dict[Any, Any]:
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"""
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Normalize all data in the data_dictionary according to the training dataset
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:params:
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:data_dictionary: dictionary containing the cleaned and split training/test data/labels
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:returns:
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:data_dictionary: updated dictionary with standardized values.
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"""
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# standardize the data by training stats
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train_max = data_dictionary["train_features"].max()
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train_min = data_dictionary["train_features"].min()
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data_dictionary["train_features"] = (
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2 * (data_dictionary["train_features"] - train_min) / (train_max - train_min) - 1
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)
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data_dictionary["test_features"] = (
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2 * (data_dictionary["test_features"] - train_min) / (train_max - train_min) - 1
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)
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for item in train_max.keys():
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self.data[item + "_max"] = train_max[item]
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self.data[item + "_min"] = train_min[item]
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for item in data_dictionary["train_labels"].keys():
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if data_dictionary["train_labels"][item].dtype == object:
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continue
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train_labels_max = data_dictionary["train_labels"][item].max()
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train_labels_min = data_dictionary["train_labels"][item].min()
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data_dictionary["train_labels"][item] = (
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2
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* (data_dictionary["train_labels"][item] - train_labels_min)
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/ (train_labels_max - train_labels_min)
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- 1
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)
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if self.freqai_config.get('data_split_parameters', {}).get('test_size', 0.1) != 0:
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data_dictionary["test_labels"][item] = (
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2
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* (data_dictionary["test_labels"][item] - train_labels_min)
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/ (train_labels_max - train_labels_min)
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- 1
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)
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self.data[f"{item}_max"] = train_labels_max # .to_dict()
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self.data[f"{item}_min"] = train_labels_min # .to_dict()
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return data_dictionary
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def normalize_data_from_metadata(self, df: DataFrame) -> DataFrame:
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"""
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Normalize a set of data using the mean and standard deviation from
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the associated training data.
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:param df: Dataframe to be standardized
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"""
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for item in df.keys():
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df[item] = (
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2
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* (df[item] - self.data[f"{item}_min"])
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/ (self.data[f"{item}_max"] - self.data[f"{item}_min"])
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- 1
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)
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return df
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def denormalize_labels_from_metadata(self, df: DataFrame) -> DataFrame:
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"""
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Normalize a set of data using the mean and standard deviation from
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the associated training data.
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:param df: Dataframe of predictions to be denormalized
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"""
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for label in df.columns:
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if df[label].dtype == object:
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continue
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df[label] = (
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(df[label] + 1)
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* (self.data[f"{label}_max"] - self.data[f"{label}_min"])
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/ 2
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) + self.data[f"{label}_min"]
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return df
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def split_timerange(
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self, tr: str, train_split: int = 28, bt_split: float = 7
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) -> Tuple[list, list]:
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"""
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Function which takes a single time range (tr) and splits it
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into sub timeranges to train and backtest on based on user input
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tr: str, full timerange to train on
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train_split: the period length for the each training (days). Specified in user
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configuration file
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bt_split: the backtesting length (days). Specified in user configuration file
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"""
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if not isinstance(train_split, int) or train_split < 1:
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raise OperationalException(
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f"train_period_days must be an integer greater than 0. Got {train_split}."
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)
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train_period_days = train_split * SECONDS_IN_DAY
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bt_period = bt_split * SECONDS_IN_DAY
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full_timerange = TimeRange.parse_timerange(tr)
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config_timerange = TimeRange.parse_timerange(self.config["timerange"])
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if config_timerange.stopts == 0:
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config_timerange.stopts = int(
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datetime.datetime.now(tz=datetime.timezone.utc).timestamp()
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)
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timerange_train = copy.deepcopy(full_timerange)
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timerange_backtest = copy.deepcopy(full_timerange)
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tr_training_list = []
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tr_backtesting_list = []
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tr_training_list_timerange = []
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tr_backtesting_list_timerange = []
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first = True
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while True:
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if not first:
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timerange_train.startts = timerange_train.startts + int(bt_period)
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timerange_train.stopts = timerange_train.startts + train_period_days
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first = False
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start = datetime.datetime.utcfromtimestamp(timerange_train.startts)
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stop = datetime.datetime.utcfromtimestamp(timerange_train.stopts)
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tr_training_list.append(start.strftime("%Y%m%d") + "-" + stop.strftime("%Y%m%d"))
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tr_training_list_timerange.append(copy.deepcopy(timerange_train))
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# associated backtest period
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timerange_backtest.startts = timerange_train.stopts
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timerange_backtest.stopts = timerange_backtest.startts + int(bt_period)
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if timerange_backtest.stopts > config_timerange.stopts:
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timerange_backtest.stopts = config_timerange.stopts
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start = datetime.datetime.utcfromtimestamp(timerange_backtest.startts)
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stop = datetime.datetime.utcfromtimestamp(timerange_backtest.stopts)
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tr_backtesting_list.append(start.strftime("%Y%m%d") + "-" + stop.strftime("%Y%m%d"))
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tr_backtesting_list_timerange.append(copy.deepcopy(timerange_backtest))
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# ensure we are predicting on exactly same amount of data as requested by user defined
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# --timerange
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if timerange_backtest.stopts == config_timerange.stopts:
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break
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# print(tr_training_list, tr_backtesting_list)
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return tr_training_list_timerange, tr_backtesting_list_timerange
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def slice_dataframe(self, timerange: TimeRange, df: DataFrame) -> DataFrame:
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"""
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Given a full dataframe, extract the user desired window
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:param tr: timerange string that we wish to extract from df
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:param df: Dataframe containing all candles to run the entire backtest. Here
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it is sliced down to just the present training period.
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"""
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start = datetime.datetime.fromtimestamp(timerange.startts, tz=datetime.timezone.utc)
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stop = datetime.datetime.fromtimestamp(timerange.stopts, tz=datetime.timezone.utc)
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df = df.loc[df["date"] >= start, :]
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df = df.loc[df["date"] <= stop, :]
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return df
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def principal_component_analysis(self) -> None:
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"""
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Performs Principal Component Analysis on the data for dimensionality reduction
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and outlier detection (see self.remove_outliers())
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No parameters or returns, it acts on the data_dictionary held by the DataHandler.
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"""
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from sklearn.decomposition import PCA # avoid importing if we dont need it
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n_components = self.data_dictionary["train_features"].shape[1]
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pca = PCA(n_components=n_components)
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pca = pca.fit(self.data_dictionary["train_features"])
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n_keep_components = np.argmin(pca.explained_variance_ratio_.cumsum() < 0.999)
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pca2 = PCA(n_components=n_keep_components)
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self.data["n_kept_components"] = n_keep_components
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pca2 = pca2.fit(self.data_dictionary["train_features"])
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logger.info("reduced feature dimension by %s", n_components - n_keep_components)
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logger.info("explained variance %f", np.sum(pca2.explained_variance_ratio_))
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train_components = pca2.transform(self.data_dictionary["train_features"])
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test_components = pca2.transform(self.data_dictionary["test_features"])
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self.data_dictionary["train_features"] = pd.DataFrame(
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data=train_components,
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columns=["PC" + str(i) for i in range(0, n_keep_components)],
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index=self.data_dictionary["train_features"].index,
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)
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# keeping a copy of the non-transformed features so we can check for errors during
|
|
# model load from disk
|
|
self.data["training_features_list_raw"] = copy.deepcopy(self.training_features_list)
|
|
self.training_features_list = self.data_dictionary["train_features"].columns
|
|
|
|
if self.freqai_config.get('data_split_parameters', {}).get('test_size', 0.1) != 0:
|
|
self.data_dictionary["test_features"] = pd.DataFrame(
|
|
data=test_components,
|
|
columns=["PC" + str(i) for i in range(0, n_keep_components)],
|
|
index=self.data_dictionary["test_features"].index,
|
|
)
|
|
|
|
self.data["n_kept_components"] = n_keep_components
|
|
self.pca = pca2
|
|
|
|
logger.info(f"PCA reduced total features from {n_components} to {n_keep_components}")
|
|
|
|
if not self.data_path.is_dir():
|
|
self.data_path.mkdir(parents=True, exist_ok=True)
|
|
|
|
return None
|
|
|
|
def pca_transform(self, filtered_dataframe: DataFrame) -> None:
|
|
"""
|
|
Use an existing pca transform to transform data into components
|
|
:params:
|
|
filtered_dataframe: DataFrame = the cleaned dataframe
|
|
"""
|
|
pca_components = self.pca.transform(filtered_dataframe)
|
|
self.data_dictionary["prediction_features"] = pd.DataFrame(
|
|
data=pca_components,
|
|
columns=["PC" + str(i) for i in range(0, self.data["n_kept_components"])],
|
|
index=filtered_dataframe.index,
|
|
)
|
|
|
|
def compute_distances(self) -> float:
|
|
"""
|
|
Compute distances between each training point and every other training
|
|
point. This metric defines the neighborhood of trained data and is used
|
|
for prediction confidence in the Dissimilarity Index
|
|
"""
|
|
# logger.info("computing average mean distance for all training points")
|
|
pairwise = pairwise_distances(
|
|
self.data_dictionary["train_features"], n_jobs=self.thread_count)
|
|
avg_mean_dist = pairwise.mean(axis=1).mean()
|
|
|
|
return avg_mean_dist
|
|
|
|
def use_SVM_to_remove_outliers(self, predict: bool) -> None:
|
|
"""
|
|
Build/inference a Support Vector Machine to detect outliers
|
|
in training data and prediction
|
|
:params:
|
|
predict: bool = If true, inference an existing SVM model, else construct one
|
|
"""
|
|
|
|
if self.keras:
|
|
logger.warning(
|
|
"SVM outlier removal not currently supported for Keras based models. "
|
|
"Skipping user requested function."
|
|
)
|
|
if predict:
|
|
self.do_predict = np.ones(len(self.data_dictionary["prediction_features"]))
|
|
return
|
|
|
|
if predict:
|
|
if not self.svm_model:
|
|
logger.warning("No svm model available for outlier removal")
|
|
return
|
|
y_pred = self.svm_model.predict(self.data_dictionary["prediction_features"])
|
|
do_predict = np.where(y_pred == -1, 0, y_pred)
|
|
|
|
if (len(do_predict) - do_predict.sum()) > 0:
|
|
logger.info(f"SVM tossed {len(do_predict) - do_predict.sum()} predictions.")
|
|
self.do_predict += do_predict
|
|
self.do_predict -= 1
|
|
|
|
else:
|
|
# use SGDOneClassSVM to increase speed?
|
|
svm_params = self.freqai_config["feature_parameters"].get(
|
|
"svm_params", {"shuffle": False, "nu": 0.1})
|
|
self.svm_model = linear_model.SGDOneClassSVM(**svm_params).fit(
|
|
self.data_dictionary["train_features"]
|
|
)
|
|
y_pred = self.svm_model.predict(self.data_dictionary["train_features"])
|
|
dropped_points = np.where(y_pred == -1, 0, y_pred)
|
|
# keep_index = np.where(y_pred == 1)
|
|
self.data_dictionary["train_features"] = self.data_dictionary["train_features"][
|
|
(y_pred == 1)
|
|
]
|
|
self.data_dictionary["train_labels"] = self.data_dictionary["train_labels"][
|
|
(y_pred == 1)
|
|
]
|
|
self.data_dictionary["train_weights"] = self.data_dictionary["train_weights"][
|
|
(y_pred == 1)
|
|
]
|
|
|
|
logger.info(
|
|
f"SVM tossed {len(y_pred) - dropped_points.sum()}"
|
|
f" train points from {len(y_pred)} total points."
|
|
)
|
|
|
|
# same for test data
|
|
# TODO: This (and the part above) could be refactored into a separate function
|
|
# to reduce code duplication
|
|
if self.freqai_config['data_split_parameters'].get('test_size', 0.1) != 0:
|
|
y_pred = self.svm_model.predict(self.data_dictionary["test_features"])
|
|
dropped_points = np.where(y_pred == -1, 0, y_pred)
|
|
self.data_dictionary["test_features"] = self.data_dictionary["test_features"][
|
|
(y_pred == 1)
|
|
]
|
|
self.data_dictionary["test_labels"] = self.data_dictionary["test_labels"][(
|
|
y_pred == 1)]
|
|
self.data_dictionary["test_weights"] = self.data_dictionary["test_weights"][
|
|
(y_pred == 1)
|
|
]
|
|
|
|
logger.info(
|
|
f"SVM tossed {len(y_pred) - dropped_points.sum()}"
|
|
f" test points from {len(y_pred)} total points."
|
|
)
|
|
|
|
return
|
|
|
|
def use_DBSCAN_to_remove_outliers(self, predict: bool, eps=None) -> None:
|
|
"""
|
|
Use DBSCAN to cluster training data and remove "noisy" data (read outliers).
|
|
User controls this via the config param `DBSCAN_outlier_pct` which indicates the
|
|
pct of training data that they want to be considered outliers.
|
|
:params:
|
|
predict: bool = If False (training), iterate to find the best hyper parameters to match
|
|
user requested outlier percent target. If True (prediction), use the parameters
|
|
determined from the previous training to estimate if the current prediction point
|
|
is an outlier.
|
|
"""
|
|
|
|
if predict:
|
|
train_ft_df = self.data_dictionary['train_features']
|
|
pred_ft_df = self.data_dictionary['prediction_features']
|
|
num_preds = len(pred_ft_df)
|
|
df = pd.concat([train_ft_df, pred_ft_df], axis=0, ignore_index=True)
|
|
clustering = DBSCAN(eps=self.data['DBSCAN_eps'],
|
|
min_samples=self.data['DBSCAN_min_samples'],
|
|
n_jobs=self.thread_count
|
|
).fit(df)
|
|
do_predict = np.where(clustering.labels_[-num_preds:] == -1, 0, 1)
|
|
|
|
if (len(do_predict) - do_predict.sum()) > 0:
|
|
logger.info(f"DBSCAN tossed {len(do_predict) - do_predict.sum()} predictions")
|
|
self.do_predict += do_predict
|
|
self.do_predict -= 1
|
|
|
|
else:
|
|
|
|
MinPts = len(self.data_dictionary['train_features'].columns) * 2
|
|
# measure pairwise distances to train_features.shape[1]*2 nearest neighbours
|
|
neighbors = NearestNeighbors(
|
|
n_neighbors=MinPts, n_jobs=self.thread_count)
|
|
neighbors_fit = neighbors.fit(self.data_dictionary['train_features'])
|
|
distances, _ = neighbors_fit.kneighbors(self.data_dictionary['train_features'])
|
|
distances = np.sort(distances, axis=0)
|
|
index_ten_pct = int(len(distances[:, 1]) * 0.1)
|
|
distances = distances[index_ten_pct:, 1]
|
|
epsilon = distances[-1]
|
|
|
|
clustering = DBSCAN(eps=epsilon, min_samples=MinPts,
|
|
n_jobs=int(self.thread_count)).fit(
|
|
self.data_dictionary['train_features']
|
|
)
|
|
|
|
logger.info(f'DBSCAN found eps of {epsilon}.')
|
|
|
|
self.data['DBSCAN_eps'] = epsilon
|
|
self.data['DBSCAN_min_samples'] = MinPts
|
|
dropped_points = np.where(clustering.labels_ == -1, 1, 0)
|
|
|
|
self.data_dictionary['train_features'] = self.data_dictionary['train_features'][
|
|
(clustering.labels_ != -1)
|
|
]
|
|
self.data_dictionary["train_labels"] = self.data_dictionary["train_labels"][
|
|
(clustering.labels_ != -1)
|
|
]
|
|
self.data_dictionary["train_weights"] = self.data_dictionary["train_weights"][
|
|
(clustering.labels_ != -1)
|
|
]
|
|
|
|
logger.info(
|
|
f"DBSCAN tossed {dropped_points.sum()}"
|
|
f" train points from {len(clustering.labels_)}"
|
|
)
|
|
|
|
return
|
|
|
|
def find_features(self, dataframe: DataFrame) -> None:
|
|
"""
|
|
Find features in the strategy provided dataframe
|
|
:param dataframe: DataFrame = strategy provided dataframe
|
|
:return:
|
|
features: list = the features to be used for training/prediction
|
|
"""
|
|
column_names = dataframe.columns
|
|
features = [c for c in column_names if "%" in c]
|
|
labels = [c for c in column_names if "&" in c]
|
|
if not features:
|
|
raise OperationalException("Could not find any features!")
|
|
|
|
self.training_features_list = features
|
|
self.label_list = labels
|
|
|
|
def check_if_pred_in_training_spaces(self) -> None:
|
|
"""
|
|
Compares the distance from each prediction point to each training data
|
|
point. It uses this information to estimate a Dissimilarity Index (DI)
|
|
and avoid making predictions on any points that are too far away
|
|
from the training data set.
|
|
"""
|
|
|
|
distance = pairwise_distances(
|
|
self.data_dictionary["train_features"],
|
|
self.data_dictionary["prediction_features"],
|
|
n_jobs=self.thread_count,
|
|
)
|
|
|
|
self.DI_values = distance.min(axis=0) / self.data["avg_mean_dist"]
|
|
|
|
do_predict = np.where(
|
|
self.DI_values < self.freqai_config["feature_parameters"]["DI_threshold"],
|
|
1,
|
|
0,
|
|
)
|
|
|
|
if (len(do_predict) - do_predict.sum()) > 0:
|
|
logger.info(
|
|
f"DI tossed {len(do_predict) - do_predict.sum():.2f} predictions for "
|
|
"being too far from training data"
|
|
)
|
|
|
|
self.do_predict += do_predict
|
|
self.do_predict -= 1
|
|
|
|
def set_weights_higher_recent(self, num_weights: int) -> npt.ArrayLike:
|
|
"""
|
|
Set weights so that recent data is more heavily weighted during
|
|
training than older data.
|
|
"""
|
|
wfactor = self.config["freqai"]["feature_parameters"]["weight_factor"]
|
|
weights = np.exp(-np.arange(num_weights) / (wfactor * num_weights))[::-1]
|
|
return weights
|
|
|
|
def append_predictions(self, predictions: DataFrame, do_predict: npt.ArrayLike) -> None:
|
|
"""
|
|
Append backtest prediction from current backtest period to all previous periods
|
|
"""
|
|
|
|
append_df = DataFrame()
|
|
for label in predictions.columns:
|
|
append_df[label] = predictions[label]
|
|
if append_df[label].dtype == object:
|
|
continue
|
|
append_df[f"{label}_mean"] = self.data["labels_mean"][label]
|
|
append_df[f"{label}_std"] = self.data["labels_std"][label]
|
|
|
|
append_df["do_predict"] = do_predict
|
|
if self.freqai_config["feature_parameters"].get("DI_threshold", 0) > 0:
|
|
append_df["DI_values"] = self.DI_values
|
|
|
|
if self.full_df.empty:
|
|
self.full_df = append_df
|
|
else:
|
|
self.full_df = pd.concat([self.full_df, append_df], axis=0)
|
|
|
|
return
|
|
|
|
def fill_predictions(self, dataframe):
|
|
"""
|
|
Back fill values to before the backtesting range so that the dataframe matches size
|
|
when it goes back to the strategy. These rows are not included in the backtest.
|
|
"""
|
|
|
|
len_filler = len(dataframe) - len(self.full_df.index) # startup_candle_count
|
|
filler_df = pd.DataFrame(
|
|
np.zeros((len_filler, len(self.full_df.columns))), columns=self.full_df.columns
|
|
)
|
|
|
|
self.full_df = pd.concat([filler_df, self.full_df], axis=0, ignore_index=True)
|
|
|
|
to_keep = [col for col in dataframe.columns if not col.startswith("&")]
|
|
self.return_dataframe = pd.concat([dataframe[to_keep], self.full_df], axis=1)
|
|
|
|
self.full_df = DataFrame()
|
|
|
|
return
|
|
|
|
def create_fulltimerange(self, backtest_tr: str, backtest_period_days: int) -> str:
|
|
|
|
if not isinstance(backtest_period_days, int):
|
|
raise OperationalException("backtest_period_days must be an integer")
|
|
|
|
if backtest_period_days < 0:
|
|
raise OperationalException("backtest_period_days must be positive")
|
|
|
|
backtest_timerange = TimeRange.parse_timerange(backtest_tr)
|
|
|
|
if backtest_timerange.stopts == 0:
|
|
# typically open ended time ranges do work, however, there are some edge cases where
|
|
# it does not. accommodating these kinds of edge cases just to allow open-ended
|
|
# timerange is not high enough priority to warrant the effort. It is safer for now
|
|
# to simply ask user to add their end date
|
|
raise OperationalException("FreqAI backtesting does not allow open ended timeranges. "
|
|
"Please indicate the end date of your desired backtesting. "
|
|
"timerange.")
|
|
# backtest_timerange.stopts = int(
|
|
# datetime.datetime.now(tz=datetime.timezone.utc).timestamp()
|
|
# )
|
|
|
|
backtest_timerange.startts = (
|
|
backtest_timerange.startts - backtest_period_days * SECONDS_IN_DAY
|
|
)
|
|
start = datetime.datetime.utcfromtimestamp(backtest_timerange.startts)
|
|
stop = datetime.datetime.utcfromtimestamp(backtest_timerange.stopts)
|
|
full_timerange = start.strftime("%Y%m%d") + "-" + stop.strftime("%Y%m%d")
|
|
|
|
self.full_path = Path(
|
|
self.config["user_data_dir"] / "models" / f"{self.freqai_config['identifier']}"
|
|
)
|
|
|
|
config_path = Path(self.config["config_files"][0])
|
|
|
|
if not self.full_path.is_dir():
|
|
self.full_path.mkdir(parents=True, exist_ok=True)
|
|
shutil.copy(
|
|
config_path.resolve(),
|
|
Path(self.full_path / config_path.parts[-1]),
|
|
)
|
|
|
|
return full_timerange
|
|
|
|
def check_if_model_expired(self, trained_timestamp: int) -> bool:
|
|
"""
|
|
A model age checker to determine if the model is trustworthy based on user defined
|
|
`expiration_hours` in the configuration file.
|
|
:param trained_timestamp: int = The time of training for the most recent model.
|
|
:return:
|
|
bool = If the model is expired or not.
|
|
"""
|
|
time = datetime.datetime.now(tz=datetime.timezone.utc).timestamp()
|
|
elapsed_time = (time - trained_timestamp) / 3600 # hours
|
|
max_time = self.freqai_config.get("expiration_hours", 0)
|
|
if max_time > 0:
|
|
return elapsed_time > max_time
|
|
else:
|
|
return False
|
|
|
|
def check_if_new_training_required(
|
|
self, trained_timestamp: int
|
|
) -> Tuple[bool, TimeRange, TimeRange]:
|
|
|
|
time = datetime.datetime.now(tz=datetime.timezone.utc).timestamp()
|
|
trained_timerange = TimeRange()
|
|
data_load_timerange = TimeRange()
|
|
|
|
timeframes = self.freqai_config["feature_parameters"].get("include_timeframes")
|
|
|
|
max_tf_seconds = 0
|
|
for tf in timeframes:
|
|
secs = timeframe_to_seconds(tf)
|
|
if secs > max_tf_seconds:
|
|
max_tf_seconds = secs
|
|
|
|
# We notice that users like to use exotic indicators where
|
|
# they do not know the required timeperiod. Here we include a factor
|
|
# of safety by multiplying the user considered "max" by 2.
|
|
max_period = self.freqai_config["feature_parameters"].get(
|
|
"indicator_max_period_candles", 20
|
|
) * 2
|
|
additional_seconds = max_period * max_tf_seconds
|
|
|
|
if trained_timestamp != 0:
|
|
elapsed_time = (time - trained_timestamp) / SECONDS_IN_HOUR
|
|
retrain = elapsed_time > self.freqai_config.get("live_retrain_hours", 0)
|
|
if retrain:
|
|
trained_timerange.startts = int(
|
|
time - self.freqai_config.get("train_period_days", 0) * SECONDS_IN_DAY
|
|
)
|
|
trained_timerange.stopts = int(time)
|
|
# we want to load/populate indicators on more data than we plan to train on so
|
|
# because most of the indicators have a rolling timeperiod, and are thus NaNs
|
|
# unless they have data further back in time before the start of the train period
|
|
data_load_timerange.startts = int(
|
|
time
|
|
- self.freqai_config.get("train_period_days", 0) * SECONDS_IN_DAY
|
|
- additional_seconds
|
|
)
|
|
data_load_timerange.stopts = int(time)
|
|
else: # user passed no live_trained_timerange in config
|
|
trained_timerange.startts = int(
|
|
time - self.freqai_config.get("train_period_days", 0) * SECONDS_IN_DAY
|
|
)
|
|
trained_timerange.stopts = int(time)
|
|
|
|
data_load_timerange.startts = int(
|
|
time
|
|
- self.freqai_config.get("train_period_days", 0) * SECONDS_IN_DAY
|
|
- additional_seconds
|
|
)
|
|
data_load_timerange.stopts = int(time)
|
|
retrain = True
|
|
|
|
# logger.info(
|
|
# f"downloading data for "
|
|
# f"{(data_load_timerange.stopts-data_load_timerange.startts)/SECONDS_IN_DAY:.2f} "
|
|
# " days. "
|
|
# f"Extension of {additional_seconds/SECONDS_IN_DAY:.2f} days"
|
|
# )
|
|
|
|
return retrain, trained_timerange, data_load_timerange
|
|
|
|
def set_new_model_names(self, pair: str, trained_timerange: TimeRange):
|
|
|
|
coin, _ = pair.split("/")
|
|
self.data_path = Path(
|
|
self.full_path
|
|
/ f"sub-train-{pair.split('/')[0]}_{int(trained_timerange.stopts)}"
|
|
)
|
|
|
|
self.model_filename = f"cb_{coin.lower()}_{int(trained_timerange.stopts)}"
|
|
|
|
def download_all_data_for_training(self, timerange: TimeRange, dp: DataProvider) -> None:
|
|
"""
|
|
Called only once upon start of bot to download the necessary data for
|
|
populating indicators and training the model.
|
|
:param timerange: TimeRange = The full data timerange for populating the indicators
|
|
and training the model.
|
|
:param dp: DataProvider instance attached to the strategy
|
|
"""
|
|
new_pairs_days = int((timerange.stopts - timerange.startts) / SECONDS_IN_DAY)
|
|
if not dp._exchange:
|
|
# Not realistic - this is only called in live mode.
|
|
raise OperationalException("Dataprovider did not have an exchange attached.")
|
|
refresh_backtest_ohlcv_data(
|
|
dp._exchange,
|
|
pairs=self.all_pairs,
|
|
timeframes=self.freqai_config["feature_parameters"].get("include_timeframes"),
|
|
datadir=self.config["datadir"],
|
|
timerange=timerange,
|
|
new_pairs_days=new_pairs_days,
|
|
erase=False,
|
|
data_format=self.config.get("dataformat_ohlcv", "json"),
|
|
trading_mode=self.config.get("trading_mode", "spot"),
|
|
prepend=self.config.get("prepend_data", False),
|
|
)
|
|
|
|
def set_all_pairs(self) -> None:
|
|
|
|
self.all_pairs = copy.deepcopy(
|
|
self.freqai_config["feature_parameters"].get("include_corr_pairlist", [])
|
|
)
|
|
for pair in self.config.get("exchange", "").get("pair_whitelist"):
|
|
if pair not in self.all_pairs:
|
|
self.all_pairs.append(pair)
|
|
|
|
def use_strategy_to_populate_indicators(
|
|
self,
|
|
strategy: IStrategy,
|
|
corr_dataframes: dict = {},
|
|
base_dataframes: dict = {},
|
|
pair: str = "",
|
|
prediction_dataframe: DataFrame = pd.DataFrame(),
|
|
) -> DataFrame:
|
|
"""
|
|
Use the user defined strategy for populating indicators during
|
|
retrain
|
|
:params:
|
|
strategy: IStrategy = user defined strategy object
|
|
corr_dataframes: dict = dict containing the informative pair dataframes
|
|
(for user defined timeframes)
|
|
base_dataframes: dict = dict containing the current pair dataframes
|
|
(for user defined timeframes)
|
|
metadata: dict = strategy furnished pair metadata
|
|
:returns:
|
|
dataframe: DataFrame = dataframe containing populated indicators
|
|
"""
|
|
|
|
# for prediction dataframe creation, we let dataprovider handle everything in the strategy
|
|
# so we create empty dictionaries, which allows us to pass None to
|
|
# `populate_any_indicators()`. Signaling we want the dp to give us the live dataframe.
|
|
tfs = self.freqai_config["feature_parameters"].get("include_timeframes")
|
|
pairs = self.freqai_config["feature_parameters"].get("include_corr_pairlist", [])
|
|
if not prediction_dataframe.empty:
|
|
dataframe = prediction_dataframe.copy()
|
|
for tf in tfs:
|
|
base_dataframes[tf] = None
|
|
for p in pairs:
|
|
if p not in corr_dataframes:
|
|
corr_dataframes[p] = {}
|
|
corr_dataframes[p][tf] = None
|
|
else:
|
|
dataframe = base_dataframes[self.config["timeframe"]].copy()
|
|
|
|
sgi = False
|
|
for tf in tfs:
|
|
if tf == tfs[-1]:
|
|
sgi = True # doing this last allows user to use all tf raw prices in labels
|
|
dataframe = strategy.populate_any_indicators(
|
|
pair,
|
|
dataframe.copy(),
|
|
tf,
|
|
informative=base_dataframes[tf],
|
|
set_generalized_indicators=sgi
|
|
)
|
|
if pairs:
|
|
for i in pairs:
|
|
if pair in i:
|
|
continue # dont repeat anything from whitelist
|
|
dataframe = strategy.populate_any_indicators(
|
|
i,
|
|
dataframe.copy(),
|
|
tf,
|
|
informative=corr_dataframes[i][tf]
|
|
)
|
|
|
|
return dataframe
|
|
|
|
def fit_labels(self) -> None:
|
|
"""
|
|
Fit the labels with a gaussian distribution
|
|
"""
|
|
import scipy as spy
|
|
|
|
self.data["labels_mean"], self.data["labels_std"] = {}, {}
|
|
for label in self.data_dictionary["train_labels"].columns:
|
|
if self.data_dictionary["train_labels"][label].dtype == object:
|
|
continue
|
|
f = spy.stats.norm.fit(self.data_dictionary["train_labels"][label])
|
|
self.data["labels_mean"][label], self.data["labels_std"][label] = f[0], f[1]
|
|
|
|
# KEEPME incase we want to let user start to grab quantiles.
|
|
# upper_q = spy.stats.norm.ppf(self.freqai_config['feature_parameters'][
|
|
# 'target_quantile'], *f)
|
|
# lower_q = spy.stats.norm.ppf(1 - self.freqai_config['feature_parameters'][
|
|
# 'target_quantile'], *f)
|
|
# self.data["upper_quantile"] = upper_q
|
|
# self.data["lower_quantile"] = lower_q
|
|
return
|
|
|
|
def remove_features_from_df(self, dataframe: DataFrame) -> DataFrame:
|
|
"""
|
|
Remove the features from the dataframe before returning it to strategy. This keeps it
|
|
compact for Frequi purposes.
|
|
"""
|
|
to_keep = [
|
|
col for col in dataframe.columns if not col.startswith("%") or col.startswith("%%")
|
|
]
|
|
return dataframe[to_keep]
|
|
|
|
def get_current_trade_database(self) -> None:
|
|
|
|
if self.database_path is None:
|
|
logger.warning('No trade database found. Skipping analysis.')
|
|
return
|
|
|
|
data = sqlite3.connect(self.database_name)
|
|
query = data.execute("SELECT * From trades")
|
|
cols = [column[0] for column in query.description]
|
|
df = pd.DataFrame.from_records(data=query.fetchall(), columns=cols)
|
|
self.trade_database_df = df.dropna(subset='close_date')
|
|
data.close()
|
|
|
|
def np_encoder(self, object):
|
|
if isinstance(object, np.generic):
|
|
return object.item()
|
|
|
|
# Functions containing useful data manipulation examples. but not actively in use.
|
|
|
|
# Possibly phasing these outlier removal methods below out in favor of
|
|
# use_SVM_to_remove_outliers (computationally more efficient and apparently higher performance).
|
|
# But these have good data manipulation examples, so keep them commented here for now.
|
|
|
|
# def determine_statistical_distributions(self) -> None:
|
|
# from fitter import Fitter
|
|
|
|
# logger.info('Determining best model for all features, may take some time')
|
|
|
|
# def compute_quantiles(ft):
|
|
# f = Fitter(self.data_dictionary["train_features"][ft],
|
|
# distributions=['gamma', 'cauchy', 'laplace',
|
|
# 'beta', 'uniform', 'lognorm'])
|
|
# f.fit()
|
|
# # f.summary()
|
|
# dist = list(f.get_best().items())[0][0]
|
|
# params = f.get_best()[dist]
|
|
# upper_q = getattr(spy.stats, list(f.get_best().items())[0][0]).ppf(0.999, **params)
|
|
# lower_q = getattr(spy.stats, list(f.get_best().items())[0][0]).ppf(0.001, **params)
|
|
|
|
# return ft, upper_q, lower_q, dist
|
|
|
|
# quantiles_tuple = Parallel(n_jobs=-1)(
|
|
# delayed(compute_quantiles)(ft) for ft in self.data_dictionary[
|
|
# 'train_features'].columns)
|
|
|
|
# df = pd.DataFrame(quantiles_tuple, columns=['features', 'upper_quantiles',
|
|
# 'lower_quantiles', 'dist'])
|
|
# self.data_dictionary['upper_quantiles'] = df['upper_quantiles']
|
|
# self.data_dictionary['lower_quantiles'] = df['lower_quantiles']
|
|
|
|
# return
|
|
|
|
# def remove_outliers(self, predict: bool) -> None:
|
|
# """
|
|
# Remove data that looks like an outlier based on the distribution of each
|
|
# variable.
|
|
# :params:
|
|
# :predict: boolean which tells the function if this is prediction data or
|
|
# training data coming in.
|
|
# """
|
|
|
|
# lower_quantile = self.data_dictionary["lower_quantiles"].to_numpy()
|
|
# upper_quantile = self.data_dictionary["upper_quantiles"].to_numpy()
|
|
|
|
# if predict:
|
|
|
|
# df = self.data_dictionary["prediction_features"][
|
|
# (self.data_dictionary["prediction_features"] < upper_quantile)
|
|
# & (self.data_dictionary["prediction_features"] > lower_quantile)
|
|
# ]
|
|
# drop_index = pd.isnull(df).any(1)
|
|
# self.data_dictionary["prediction_features"].fillna(0, inplace=True)
|
|
# drop_index = ~drop_index
|
|
# do_predict = np.array(drop_index.replace(True, 1).replace(False, 0))
|
|
|
|
# logger.info(
|
|
# "remove_outliers() tossed %s predictions",
|
|
# len(do_predict) - do_predict.sum(),
|
|
# )
|
|
# self.do_predict += do_predict
|
|
# self.do_predict -= 1
|
|
|
|
# else:
|
|
|
|
# filter_train_df = self.data_dictionary["train_features"][
|
|
# (self.data_dictionary["train_features"] < upper_quantile)
|
|
# & (self.data_dictionary["train_features"] > lower_quantile)
|
|
# ]
|
|
# drop_index = pd.isnull(filter_train_df).any(1)
|
|
# drop_index = drop_index.replace(True, 1).replace(False, 0)
|
|
# self.data_dictionary["train_features"] = self.data_dictionary["train_features"][
|
|
# (drop_index == 0)
|
|
# ]
|
|
# self.data_dictionary["train_labels"] = self.data_dictionary["train_labels"][
|
|
# (drop_index == 0)
|
|
# ]
|
|
# self.data_dictionary["train_weights"] = self.data_dictionary["train_weights"][
|
|
# (drop_index == 0)
|
|
# ]
|
|
|
|
# logger.info(
|
|
# f'remove_outliers() tossed {drop_index.sum()}'
|
|
# f' training points from {len(filter_train_df)}'
|
|
# )
|
|
|
|
# # do the same for the test data
|
|
# filter_test_df = self.data_dictionary["test_features"][
|
|
# (self.data_dictionary["test_features"] < upper_quantile)
|
|
# & (self.data_dictionary["test_features"] > lower_quantile)
|
|
# ]
|
|
# drop_index = pd.isnull(filter_test_df).any(1)
|
|
# drop_index = drop_index.replace(True, 1).replace(False, 0)
|
|
# self.data_dictionary["test_labels"] = self.data_dictionary["test_labels"][
|
|
# (drop_index == 0)
|
|
# ]
|
|
# self.data_dictionary["test_features"] = self.data_dictionary["test_features"][
|
|
# (drop_index == 0)
|
|
# ]
|
|
# self.data_dictionary["test_weights"] = self.data_dictionary["test_weights"][
|
|
# (drop_index == 0)
|
|
# ]
|
|
|
|
# logger.info(
|
|
# f'remove_outliers() tossed {drop_index.sum()}'
|
|
# f' test points from {len(filter_test_df)}'
|
|
# )
|
|
|
|
# return
|
|
|
|
# def standardize_data(self, data_dictionary: Dict) -> Dict[Any, Any]:
|
|
# """
|
|
# standardize all data in the data_dictionary according to the training dataset
|
|
# :params:
|
|
# :data_dictionary: dictionary containing the cleaned and split training/test data/labels
|
|
# :returns:
|
|
# :data_dictionary: updated dictionary with standardized values.
|
|
# """
|
|
# # standardize the data by training stats
|
|
# train_mean = data_dictionary["train_features"].mean()
|
|
# train_std = data_dictionary["train_features"].std()
|
|
# data_dictionary["train_features"] = (
|
|
# data_dictionary["train_features"] - train_mean
|
|
# ) / train_std
|
|
# data_dictionary["test_features"] = (
|
|
# data_dictionary["test_features"] - train_mean
|
|
# ) / train_std
|
|
|
|
# train_labels_std = data_dictionary["train_labels"].std()
|
|
# train_labels_mean = data_dictionary["train_labels"].mean()
|
|
# data_dictionary["train_labels"] = (
|
|
# data_dictionary["train_labels"] - train_labels_mean
|
|
# ) / train_labels_std
|
|
# data_dictionary["test_labels"] = (
|
|
# data_dictionary["test_labels"] - train_labels_mean
|
|
# ) / train_labels_std
|
|
|
|
# for item in train_std.keys():
|
|
# self.data[item + "_std"] = train_std[item]
|
|
# self.data[item + "_mean"] = train_mean[item]
|
|
|
|
# self.data["labels_std"] = train_labels_std
|
|
# self.data["labels_mean"] = train_labels_mean
|
|
|
|
# return data_dictionary
|
|
|
|
# def standardize_data_from_metadata(self, df: DataFrame) -> DataFrame:
|
|
# """
|
|
# Normalizes a set of data using the mean and standard deviation from
|
|
# the associated training data.
|
|
# :params:
|
|
# :df: Dataframe to be standardized
|
|
# """
|
|
|
|
# for item in df.keys():
|
|
# df[item] = (df[item] - self.data[item + "_mean"]) / self.data[item + "_std"]
|
|
|
|
# return df
|