freqtrade_origin/freqtrade/freqai/prediction_models/CNNPredictionModel.py

import logging
from typing import Any, Dict, Tuple

import numpy as np
import tensorflow as tf
from pandas import DataFrame
from tensorflow.keras.layers import Conv1D, Dense, Input
from tensorflow.keras.models import Model

from freqtrade.exceptions import OperationalException
from freqtrade.freqai.base_models.BaseTensorFlowModel import BaseTensorFlowModel, WindowGenerator
from freqtrade.freqai.data_kitchen import FreqaiDataKitchen


logger = logging.getLogger(__name__)

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

MAX_EPOCHS = 10


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

    def fit(self, data_dictionary: Dict[str, Any], dk: FreqaiDataKitchen) -> 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,
        )

        model = self.create_model(input_dims, n_labels)

        steps_per_epoch = np.ceil(len(test_df) / BATCH_SIZE)
        lr_schedule = tf.keras.optimizers.schedules.InverseTimeDecay(
            0.001, decay_steps=steps_per_epoch * 1000, decay_rate=1, staircase=False
        )

        early_stopping = tf.keras.callbacks.EarlyStopping(
            monitor="loss", patience=3, mode="min", min_delta=0.0001
        )

        model.compile(
            loss=tf.losses.MeanSquaredError(),
            optimizer=tf.optimizers.Adam(lr_schedule),
            metrics=[tf.metrics.MeanAbsoluteError()],
        )

        if self.freqai_info.get('data_split_parameters', {}).get('test_size', 0.1) == 0:
            val_data = None
        else:
            val_data = w1.val

        model.fit(
            w1.train,
            epochs=MAX_EPOCHS,
            shuffle=False,
            validation_data=val_data,
            callbacks=[early_stopping],
            verbose=1,
        )

        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)

        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, 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 create_model(self, input_dims, n_labels) -> Any:

        input_layer = Input(shape=(input_dims[1], input_dims[2]))
        Layer_1 = Conv1D(filters=32, kernel_size=(self.CONV_WIDTH,), activation="relu")(input_layer)
        Layer_3 = Dense(units=32, activation="relu")(Layer_1)
        output_layer = Dense(units=n_labels)(Layer_3)
        return Model(inputs=input_layer, outputs=output_layer)