freqtrade_origin/freqtrade/freqai/prediction_models/RLPredictionModel.py

import logging
from typing import Any, Dict, Tuple
#from matplotlib.colors import DivergingNorm

from pandas import DataFrame
import pandas as pd
from freqtrade.exceptions import OperationalException
from freqtrade.freqai.data_kitchen import FreqaiDataKitchen
import tensorflow as tf
from freqtrade.freqai.prediction_models.BaseTensorFlowModel import BaseTensorFlowModel
from freqtrade.freqai.freqai_interface import IFreqaiModel
from tensorflow.keras.layers import Input, Conv1D, Dense, MaxPooling1D, Flatten, Dropout
from tensorflow.keras.models import Model
import numpy as np
import copy

from keras.layers import *
import random


logger = logging.getLogger(__name__)

# tf.config.run_functions_eagerly(True)
# tf.data.experimental.enable_debug_mode()

import os
os.environ['TF_CPP_MIN_LOG_LEVEL'] = '2'
os.environ["CUDA_VISIBLE_DEVICES"] = "-1"

MAX_EPOCHS = 10
LOOKBACK = 8


class RLPredictionModel_v2(IFreqaiModel):
    """
    User created prediction model. The class needs to override three necessary
    functions, predict(), fit().
    """

    def fit(self, data_dictionary: Dict, pair) -> Any:
        """
        User sets up the training and test data to fit their desired model here
        :params:
        :data_dictionary: the dictionary constructed by DataHandler to hold
        all the training and test data/labels.
        """

        train_df = data_dictionary["train_features"]
        train_labels = data_dictionary["train_labels"]
        test_df = data_dictionary["test_features"]
        test_labels = data_dictionary["test_labels"]
        n_labels = len(train_labels.columns)
        if n_labels > 1:
            raise OperationalException(
                "Neural Net not yet configured for multi-targets. Please "
                " reduce number of targets to 1 in strategy."
            )

        n_features = len(data_dictionary["train_features"].columns)
        BATCH_SIZE = self.freqai_info.get("batch_size", 64)
        input_dims = [BATCH_SIZE, self.CONV_WIDTH, n_features]


        w1 = WindowGenerator(
            input_width=self.CONV_WIDTH,
            label_width=1,
            shift=1,
            train_df=train_df,
            val_df=test_df,
            train_labels=train_labels,
            val_labels=test_labels,
            batch_size=BATCH_SIZE,
        )


        # train_agent()
        #pair = self.dd.historical_data[pair]
        #gym_env = FreqtradeEnv(data=train_df, prices=0.01, windows_size=100, pair=pair, stake_amount=100)

        # sep = '/'
        # coin = pair.split(sep, 1)[0]

        # # df1 = train_df.filter(regex='price')
        # # df2 = df1.filter(regex='raw')

        # # df3 = df2.filter(regex=f"{coin}")
        # # print(df3)

        # price = train_df[f"%-{coin}raw_price_5m"]
        # gym_env = RLPrediction_GymAnytrading(signal_features=train_df, prices=price, window_size=100)
        # sac = RLPrediction_Agent(gym_env)

        # print(sac)

        # return 0


        return model

    def predict(
        self, unfiltered_dataframe: DataFrame, dk: FreqaiDataKitchen, first=True
    ) -> Tuple[DataFrame, DataFrame]:
        """
        Filter the prediction features data and predict with it.
        :param: unfiltered_dataframe: Full dataframe for the current backtest period.
        :return:
        :predictions: np.array of predictions
        :do_predict: np.array of 1s and 0s to indicate places where freqai needed to remove
        data (NaNs) or felt uncertain about data (PCA and DI index)
        """

        dk.find_features(unfiltered_dataframe)
        filtered_dataframe, _ = dk.filter_features(
            unfiltered_dataframe, dk.training_features_list, training_filter=False
        )
        filtered_dataframe = dk.normalize_data_from_metadata(filtered_dataframe)
        dk.data_dictionary["prediction_features"] = filtered_dataframe

        # optional additional data cleaning/analysis
        self.data_cleaning_predict(dk, filtered_dataframe)

        if first:
            full_df = dk.data_dictionary["prediction_features"]

            w1 = WindowGenerator(
                input_width=self.CONV_WIDTH,
                label_width=1,
                shift=1,
                test_df=full_df,
                batch_size=len(full_df),
            )

            predictions = self.model.predict(w1.inference)
            len_diff = len(dk.do_predict) - len(predictions)
            if len_diff > 0:
                dk.do_predict = dk.do_predict[len_diff:]

        else:
            data = dk.data_dictionary["prediction_features"]
            data = tf.expand_dims(data, axis=0)
            predictions = self.model(data, training=False)

        predictions = predictions[:, 0]
        pred_df = DataFrame(predictions, columns=dk.label_list)

        pred_df = dk.denormalize_labels_from_metadata(pred_df)

        return (pred_df, np.ones(len(pred_df)))

 
    def set_initial_historic_predictions(
        self, df: DataFrame, model: Any, dk: FreqaiDataKitchen, pair: str
    ) -> None:

        pass
        # w1 = WindowGenerator(
        #     input_width=self.CONV_WIDTH, label_width=1, shift=1, test_df=df, batch_size=len(df)
        # )
        
        # trained_predictions = model.predict(w1.inference)
        # #trained_predictions = trained_predictions[:, 0, 0]
        # trained_predictions = trained_predictions[:, 0]

        # n_lost_points = len(df) - len(trained_predictions)
        # pred_df = DataFrame(trained_predictions, columns=dk.label_list)
        # zeros_df = DataFrame(np.zeros((n_lost_points, len(dk.label_list))), columns=dk.label_list)
        # pred_df = pd.concat([zeros_df, pred_df], axis=0)

        # pred_df = dk.denormalize_labels_from_metadata(pred_df)

        
        # self.dd.historic_predictions[pair] = DataFrame()
        # self.dd.historic_predictions[pair] = copy.deepcopy(pred_df)


class WindowGenerator:
    def __init__(
        self,
        input_width,
        label_width,
        shift,
        train_df=None,
        val_df=None,
        test_df=None,
        train_labels=None,
        val_labels=None,
        test_labels=None,
        batch_size=None,
    ):
        # Store the raw data.
        self.train_df = train_df
        self.val_df = val_df
        self.test_df = test_df
        self.train_labels = train_labels
        self.val_labels = val_labels
        self.test_labels = test_labels
        self.batch_size = batch_size
        self.input_width = input_width
        self.label_width = label_width
        self.shift = shift

        self.total_window_size = input_width + shift

        self.input_slice = slice(0, input_width)
        self.input_indices = np.arange(self.total_window_size)[self.input_slice]

    def make_dataset(self, data, labels=None):
        data = np.array(data, dtype=np.float32)
        if labels is not None:
            labels = np.array(labels, dtype=np.float32)
        ds = tf.keras.preprocessing.timeseries_dataset_from_array(
            data=data,
            targets=labels,
            sequence_length=self.total_window_size,
            sequence_stride=1,
            sampling_rate=1,
            shuffle=False,
            batch_size=self.batch_size,
        )

        return ds

    @property
    def train(self):


        return self.make_dataset(self.train_df, self.train_labels)

    @property
    def val(self):
        return self.make_dataset(self.val_df, self.val_labels)

    @property
    def test(self):
        return self.make_dataset(self.test_df, self.test_labels)

    @property
    def inference(self):
        return self.make_dataset(self.test_df)

    @property
    def example(self):
        """Get and cache an example batch of `inputs, labels` for plotting."""
        result = getattr(self, "_example", None)
        if result is None:
            # No example batch was found, so get one from the `.train` dataset
            result = next(iter(self.train))
            # And cache it for next time
            self._example = result
        return result
callback function and TDQN model added 2022-08-13 15:48:58 +00:00			`import logging`
			`from typing import Any, Dict, Tuple`
			`#from matplotlib.colors import DivergingNorm`

			`from pandas import DataFrame`
			`import pandas as pd`
			`from freqtrade.exceptions import OperationalException`
			`from freqtrade.freqai.data_kitchen import FreqaiDataKitchen`
			`import tensorflow as tf`
			`from freqtrade.freqai.prediction_models.BaseTensorFlowModel import BaseTensorFlowModel`
			`from freqtrade.freqai.freqai_interface import IFreqaiModel`
			`from tensorflow.keras.layers import Input, Conv1D, Dense, MaxPooling1D, Flatten, Dropout`
			`from tensorflow.keras.models import Model`
			`import numpy as np`
			`import copy`

			`from keras.layers import *`
			`import random`


			`logger = logging.getLogger(__name__)`

			`# tf.config.run_functions_eagerly(True)`
			`# tf.data.experimental.enable_debug_mode()`

			`import os`
			`os.environ['TF_CPP_MIN_LOG_LEVEL'] = '2'`
			`os.environ["CUDA_VISIBLE_DEVICES"] = "-1"`

			`MAX_EPOCHS = 10`
			`LOOKBACK = 8`


			`class RLPredictionModel_v2(IFreqaiModel):`
			`"""`
			`User created prediction model. The class needs to override three necessary`
			`functions, predict(), fit().`
			`"""`

			`def fit(self, data_dictionary: Dict, pair) -> Any:`
			`"""`
			`User sets up the training and test data to fit their desired model here`
			`:params:`
			`:data_dictionary: the dictionary constructed by DataHandler to hold`
			`all the training and test data/labels.`
			`"""`

			`train_df = data_dictionary["train_features"]`
			`train_labels = data_dictionary["train_labels"]`
			`test_df = data_dictionary["test_features"]`
			`test_labels = data_dictionary["test_labels"]`
			`n_labels = len(train_labels.columns)`
			`if n_labels > 1:`
			`raise OperationalException(`
			`"Neural Net not yet configured for multi-targets. Please "`
			`" reduce number of targets to 1 in strategy."`
			`)`

			`n_features = len(data_dictionary["train_features"].columns)`
			`BATCH_SIZE = self.freqai_info.get("batch_size", 64)`
			`input_dims = [BATCH_SIZE, self.CONV_WIDTH, n_features]`


			`w1 = WindowGenerator(`
			`input_width=self.CONV_WIDTH,`
			`label_width=1,`
			`shift=1,`
			`train_df=train_df,`
			`val_df=test_df,`
			`train_labels=train_labels,`
			`val_labels=test_labels,`
			`batch_size=BATCH_SIZE,`
			`)`


			`# train_agent()`
			`#pair = self.dd.historical_data[pair]`
			`#gym_env = FreqtradeEnv(data=train_df, prices=0.01, windows_size=100, pair=pair, stake_amount=100)`

			`# sep = '/'`
			`# coin = pair.split(sep, 1)[0]`

			`# # df1 = train_df.filter(regex='price')`
			`# # df2 = df1.filter(regex='raw')`

			`# # df3 = df2.filter(regex=f"{coin}")`
			`# # print(df3)`

			`# price = train_df[f"%-{coin}raw_price_5m"]`
			`# gym_env = RLPrediction_GymAnytrading(signal_features=train_df, prices=price, window_size=100)`
			`# sac = RLPrediction_Agent(gym_env)`

			`# print(sac)`

			`# return 0`



			`return model`

			`def predict(`
			`self, unfiltered_dataframe: DataFrame, dk: FreqaiDataKitchen, first=True`
			`) -> Tuple[DataFrame, DataFrame]:`
			`"""`
			`Filter the prediction features data and predict with it.`
			`:param: unfiltered_dataframe: Full dataframe for the current backtest period.`
			`:return:`
			`:predictions: np.array of predictions`
			`:do_predict: np.array of 1s and 0s to indicate places where freqai needed to remove`
			`data (NaNs) or felt uncertain about data (PCA and DI index)`
			`"""`

			`dk.find_features(unfiltered_dataframe)`
			`filtered_dataframe, _ = dk.filter_features(`
			`unfiltered_dataframe, dk.training_features_list, training_filter=False`
			`)`
			`filtered_dataframe = dk.normalize_data_from_metadata(filtered_dataframe)`
			`dk.data_dictionary["prediction_features"] = filtered_dataframe`

			`# optional additional data cleaning/analysis`
			`self.data_cleaning_predict(dk, filtered_dataframe)`

			`if first:`
			`full_df = dk.data_dictionary["prediction_features"]`

			`w1 = WindowGenerator(`
			`input_width=self.CONV_WIDTH,`
			`label_width=1,`
			`shift=1,`
			`test_df=full_df,`
			`batch_size=len(full_df),`
			`)`

			`predictions = self.model.predict(w1.inference)`
			`len_diff = len(dk.do_predict) - len(predictions)`
			`if len_diff > 0:`
			`dk.do_predict = dk.do_predict[len_diff:]`

			`else:`
			`data = dk.data_dictionary["prediction_features"]`
			`data = tf.expand_dims(data, axis=0)`
			`predictions = self.model(data, training=False)`

			`predictions = predictions[:, 0]`
			`pred_df = DataFrame(predictions, columns=dk.label_list)`

			`pred_df = dk.denormalize_labels_from_metadata(pred_df)`

			`return (pred_df, np.ones(len(pred_df)))`


			`def set_initial_historic_predictions(`
			`self, df: DataFrame, model: Any, dk: FreqaiDataKitchen, pair: str`
			`) -> None:`

			`pass`
			`# w1 = WindowGenerator(`
			`# input_width=self.CONV_WIDTH, label_width=1, shift=1, test_df=df, batch_size=len(df)`
			`# )`

			`# trained_predictions = model.predict(w1.inference)`
			`# #trained_predictions = trained_predictions[:, 0, 0]`
			`# trained_predictions = trained_predictions[:, 0]`

			`# n_lost_points = len(df) - len(trained_predictions)`
			`# pred_df = DataFrame(trained_predictions, columns=dk.label_list)`
			`# zeros_df = DataFrame(np.zeros((n_lost_points, len(dk.label_list))), columns=dk.label_list)`
			`# pred_df = pd.concat([zeros_df, pred_df], axis=0)`

			`# pred_df = dk.denormalize_labels_from_metadata(pred_df)`



			`# self.dd.historic_predictions[pair] = DataFrame()`
			`# self.dd.historic_predictions[pair] = copy.deepcopy(pred_df)`


			`class WindowGenerator:`
			`def __init__(`
			`self,`
			`input_width,`
			`label_width,`
			`shift,`
			`train_df=None,`
			`val_df=None,`
			`test_df=None,`
			`train_labels=None,`
			`val_labels=None,`
			`test_labels=None,`
			`batch_size=None,`
			`):`
			`# Store the raw data.`
			`self.train_df = train_df`
			`self.val_df = val_df`
			`self.test_df = test_df`
			`self.train_labels = train_labels`
			`self.val_labels = val_labels`
			`self.test_labels = test_labels`
			`self.batch_size = batch_size`
			`self.input_width = input_width`
			`self.label_width = label_width`
			`self.shift = shift`

			`self.total_window_size = input_width + shift`

			`self.input_slice = slice(0, input_width)`
			`self.input_indices = np.arange(self.total_window_size)[self.input_slice]`

			`def make_dataset(self, data, labels=None):`
			`data = np.array(data, dtype=np.float32)`
			`if labels is not None:`
			`labels = np.array(labels, dtype=np.float32)`
			`ds = tf.keras.preprocessing.timeseries_dataset_from_array(`
			`data=data,`
			`targets=labels,`
			`sequence_length=self.total_window_size,`
			`sequence_stride=1,`
			`sampling_rate=1,`
			`shuffle=False,`
			`batch_size=self.batch_size,`
			`)`

			`return ds`

			`@property`
			`def train(self):`



			`return self.make_dataset(self.train_df, self.train_labels)`

			`@property`
			`def val(self):`
			`return self.make_dataset(self.val_df, self.val_labels)`

			`@property`
			`def test(self):`
			`return self.make_dataset(self.test_df, self.test_labels)`

			`@property`
			`def inference(self):`
			`return self.make_dataset(self.test_df)`

			`@property`
			`def example(self):`
			"""Get and cache an example batch of `inputs, labels` for plotting."""
			`result = getattr(self, "_example", None)`
			`if result is None:`
			# No example batch was found, so get one from the `.train` dataset
			`result = next(iter(self.train))`
			`# And cache it for next time`
			`self._example = result`
			`return result`