freqtrade_origin/docs/freqai-configuration.md
2023-03-22 18:15:57 +02:00

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Configuration

FreqAI is configured through the typical Freqtrade config file and the standard Freqtrade strategy. Examples of FreqAI config and strategy files can be found in config_examples/config_freqai.example.json and freqtrade/templates/FreqaiExampleStrategy.py, respectively.

Setting up the configuration file

Although there are plenty of additional parameters to choose from, as highlighted in the parameter table, a FreqAI config must at minimum include the following parameters (the parameter values are only examples):

    "freqai": {
        "enabled": true,
        "purge_old_models": 2,
        "train_period_days": 30,
        "backtest_period_days": 7,
        "identifier" : "unique-id",
        "feature_parameters" : {
            "include_timeframes": ["5m","15m","4h"],
            "include_corr_pairlist": [
                "ETH/USD",
                "LINK/USD",
                "BNB/USD"
            ],
            "label_period_candles": 24,
            "include_shifted_candles": 2,
            "indicator_periods_candles": [10, 20]
        },
        "data_split_parameters" : {
            "test_size": 0.25
        }
    }

A full example config is available in config_examples/config_freqai.example.json.

Building a FreqAI strategy

The FreqAI strategy requires including the following lines of code in the standard Freqtrade strategy:

    # user should define the maximum startup candle count (the largest number of candles
    # passed to any single indicator)
    startup_candle_count: int = 20

    def populate_indicators(self, dataframe: DataFrame, metadata: dict) -> DataFrame:

        # the model will return all labels created by user in `set_freqai_labels()`
        # (& appended targets), an indication of whether or not the prediction should be accepted,
        # the target mean/std values for each of the labels created by user in
        # `feature_engineering_*` for each training period.

        dataframe = self.freqai.start(dataframe, metadata, self)

        return dataframe

    def feature_engineering_expand_all(self, dataframe, period, **kwargs):
        """
        *Only functional with FreqAI enabled strategies*
        This function will automatically expand the defined features on the config defined
        `indicator_periods_candles`, `include_timeframes`, `include_shifted_candles`, and
        `include_corr_pairs`. In other words, a single feature defined in this function
        will automatically expand to a total of
        `indicator_periods_candles` * `include_timeframes` * `include_shifted_candles` *
        `include_corr_pairs` numbers of features added to the model.

        All features must be prepended with `%` to be recognized by FreqAI internals.

        :param df: strategy dataframe which will receive the features
        :param period: period of the indicator - usage example:
        dataframe["%-ema-period"] = ta.EMA(dataframe, timeperiod=period)
        """

        dataframe["%-rsi-period"] = ta.RSI(dataframe, timeperiod=period)
        dataframe["%-mfi-period"] = ta.MFI(dataframe, timeperiod=period)
        dataframe["%-adx-period"] = ta.ADX(dataframe, timeperiod=period)
        dataframe["%-sma-period"] = ta.SMA(dataframe, timeperiod=period)
        dataframe["%-ema-period"] = ta.EMA(dataframe, timeperiod=period)

        return dataframe

    def feature_engineering_expand_basic(self, dataframe, **kwargs):
        """
        *Only functional with FreqAI enabled strategies*
        This function will automatically expand the defined features on the config defined
        `include_timeframes`, `include_shifted_candles`, and `include_corr_pairs`.
        In other words, a single feature defined in this function
        will automatically expand to a total of
        `include_timeframes` * `include_shifted_candles` * `include_corr_pairs`
        numbers of features added to the model.

        Features defined here will *not* be automatically duplicated on user defined
        `indicator_periods_candles`

        All features must be prepended with `%` to be recognized by FreqAI internals.

        :param df: strategy dataframe which will receive the features
        dataframe["%-pct-change"] = dataframe["close"].pct_change()
        dataframe["%-ema-200"] = ta.EMA(dataframe, timeperiod=200)
        """
        dataframe["%-pct-change"] = dataframe["close"].pct_change()
        dataframe["%-raw_volume"] = dataframe["volume"]
        dataframe["%-raw_price"] = dataframe["close"]
        return dataframe

    def feature_engineering_standard(self, dataframe, **kwargs):
        """
        *Only functional with FreqAI enabled strategies*
        This optional function will be called once with the dataframe of the base timeframe.
        This is the final function to be called, which means that the dataframe entering this
        function will contain all the features and columns created by all other
        freqai_feature_engineering_* functions.

        This function is a good place to do custom exotic feature extractions (e.g. tsfresh).
        This function is a good place for any feature that should not be auto-expanded upon
        (e.g. day of the week).

        All features must be prepended with `%` to be recognized by FreqAI internals.

        :param df: strategy dataframe which will receive the features
        usage example: dataframe["%-day_of_week"] = (dataframe["date"].dt.dayofweek + 1) / 7
        """
        dataframe["%-day_of_week"] = (dataframe["date"].dt.dayofweek + 1) / 7
        dataframe["%-hour_of_day"] = (dataframe["date"].dt.hour + 1) / 25
        return dataframe

    def set_freqai_targets(self, dataframe, **kwargs):
        """
        *Only functional with FreqAI enabled strategies*
        Required function to set the targets for the model.
        All targets must be prepended with `&` to be recognized by the FreqAI internals.

        :param df: strategy dataframe which will receive the targets
        usage example: dataframe["&-target"] = dataframe["close"].shift(-1) / dataframe["close"]
        """
        dataframe["&-s_close"] = (
            dataframe["close"]
            .shift(-self.freqai_info["feature_parameters"]["label_period_candles"])
            .rolling(self.freqai_info["feature_parameters"]["label_period_candles"])
            .mean()
            / dataframe["close"]
            - 1
            )

Notice how the feature_engineering_*() is where features are added. Meanwhile set_freqai_targets() adds the labels/targets. A full example strategy is available in templates/FreqaiExampleStrategy.py.

!!! Note The self.freqai.start() function cannot be called outside the populate_indicators().

!!! Note Features must be defined in feature_engineering_*(). Defining FreqAI features in populate_indicators() will cause the algorithm to fail in live/dry mode. In order to add generalized features that are not associated with a specific pair or timeframe, you should use feature_engineering_standard() (as exemplified in freqtrade/templates/FreqaiExampleStrategy.py).

Important dataframe key patterns

Below are the values you can expect to include/use inside a typical strategy dataframe (df[]):

DataFrame Key Description
df['&*'] Any dataframe column prepended with & in set_freqai_targets() is treated as a training target (label) inside FreqAI (typically following the naming convention &-s*). For example, to predict the close price 40 candles into the future, you would set df['&-s_close'] = df['close'].shift(-self.freqai_info["feature_parameters"]["label_period_candles"]) with "label_period_candles": 40 in the config. FreqAI makes the predictions and gives them back under the same key (df['&-s_close']) to be used in populate_entry/exit_trend().
Datatype: Depends on the output of the model.
df['&*_std/mean'] Standard deviation and mean values of the defined labels during training (or live tracking with fit_live_predictions_candles). Commonly used to understand the rarity of a prediction (use the z-score as shown in templates/FreqaiExampleStrategy.py and explained here to evaluate how often a particular prediction was observed during training or historically with fit_live_predictions_candles).
Datatype: Float.
df['do_predict'] Indication of an outlier data point. The return value is integer between -2 and 2, which lets you know if the prediction is trustworthy or not. do_predict==1 means that the prediction is trustworthy. If the Dissimilarity Index (DI, see details here) of the input data point is above the threshold defined in the config, FreqAI will subtract 1 from do_predict, resulting in do_predict==0. If use_SVM_to_remove_outliers() is active, the Support Vector Machine (SVM, see details here) may also detect outliers in training and prediction data. In this case, the SVM will also subtract 1 from do_predict. If the input data point was considered an outlier by the SVM but not by the DI, or vice versa, the result will be do_predict==0. If both the DI and the SVM considers the input data point to be an outlier, the result will be do_predict==-1. As with the SVM, if use_DBSCAN_to_remove_outliers is active, DBSCAN (see details here) may also detect outliers and subtract 1 from do_predict. Hence, if both the SVM and DBSCAN are active and identify a datapoint that was above the DI threshold as an outlier, the result will be do_predict==-2. A particular case is when do_predict == 2, which means that the model has expired due to exceeding expired_hours.
Datatype: Integer between -2 and 2.
df['DI_values'] Dissimilarity Index (DI) values are proxies for the level of confidence FreqAI has in the prediction. A lower DI means the prediction is close to the training data, i.e., higher prediction confidence. See details about the DI here.
Datatype: Float.
df['%*'] Any dataframe column prepended with % in feature_engineering_*() is treated as a training feature. For example, you can include the RSI in the training feature set (similar to in templates/FreqaiExampleStrategy.py) by setting df['%-rsi']. See more details on how this is done here.
Note: Since the number of features prepended with % can multiply very quickly (10s of thousands of features are easily engineered using the multiplictative functionality of, e.g., include_shifted_candles and include_timeframes as described in the parameter table), these features are removed from the dataframe that is returned from FreqAI to the strategy. To keep a particular type of feature for plotting purposes, you would prepend it with %%.
Datatype: Depends on the output of the model.

Setting the startup_candle_count

The startup_candle_count in the FreqAI strategy needs to be set up in the same way as in the standard Freqtrade strategy (see details here). This value is used by Freqtrade to ensure that a sufficient amount of data is provided when calling the dataprovider, to avoid any NaNs at the beginning of the first training. You can easily set this value by identifying the longest period (in candle units) which is passed to the indicator creation functions (e.g., TA-Lib functions). In the presented example, startup_candle_count is 20 since this is the maximum value in indicators_periods_candles.

!!! Note There are instances where the TA-Lib functions actually require more data than just the passed period or else the feature dataset gets populated with NaNs. Anecdotally, multiplying the startup_candle_count by 2 always leads to a fully NaN free training dataset. Hence, it is typically safest to multiply the expected startup_candle_count by 2. Look out for this log message to confirm that the data is clean:

```
2022-08-31 15:14:04 - freqtrade.freqai.data_kitchen - INFO - dropped 0 training points due to NaNs in populated dataset 4319.
```

Creating a dynamic target threshold

Deciding when to enter or exit a trade can be done in a dynamic way to reflect current market conditions. FreqAI allows you to return additional information from the training of a model (more info here). For example, the &*_std/mean return values describe the statistical distribution of the target/label during the most recent training. Comparing a given prediction to these values allows you to know the rarity of the prediction. In templates/FreqaiExampleStrategy.py, the target_roi and sell_roi are defined to be 1.25 z-scores away from the mean which causes predictions that are closer to the mean to be filtered out.

dataframe["target_roi"] = dataframe["&-s_close_mean"] + dataframe["&-s_close_std"] * 1.25
dataframe["sell_roi"] = dataframe["&-s_close_mean"] - dataframe["&-s_close_std"] * 1.25

To consider the population of historical predictions for creating the dynamic target instead of information from the training as discussed above, you would set fit_live_predictions_candles in the config to the number of historical prediction candles you wish to use to generate target statistics.

    "freqai": {
        "fit_live_predictions_candles": 300,
    }

If this value is set, FreqAI will initially use the predictions from the training data and subsequently begin introducing real prediction data as it is generated. FreqAI will save this historical data to be reloaded if you stop and restart a model with the same identifier.

Using different prediction models

FreqAI has multiple example prediction model libraries that are ready to be used as is via the flag --freqaimodel. These libraries include CatBoost, LightGBM, and XGBoost regression, classification, and multi-target models, and can be found in freqai/prediction_models/.

Regression and classification models differ in what targets they predict - a regression model will predict a target of continuous values, for example what price BTC will be at tomorrow, whilst a classifier will predict a target of discrete values, for example if the price of BTC will go up tomorrow or not. This means that you have to specify your targets differently depending on which model type you are using (see details below).

All of the aforementioned model libraries implement gradient boosted decision tree algorithms. They all work on the principle of ensemble learning, where predictions from multiple simple learners are combined to get a final prediction that is more stable and generalized. The simple learners in this case are decision trees. Gradient boosting refers to the method of learning, where each simple learner is built in sequence - the subsequent learner is used to improve on the error from the previous learner. If you want to learn more about the different model libraries you can find the information in their respective docs:

There are also numerous online articles describing and comparing the algorithms. Some relatively lightweight examples would be CatBoost vs. LightGBM vs. XGBoost — Which is the best algorithm? and XGBoost, LightGBM or CatBoost — which boosting algorithm should I use?. Keep in mind that the performance of each model is highly dependent on the application and so any reported metrics might not be true for your particular use of the model.

Apart from the models already available in FreqAI, it is also possible to customize and create your own prediction models using the IFreqaiModel class. You are encouraged to inherit fit(), train(), and predict() to customize various aspects of the training procedures. You can place custom FreqAI models in user_data/freqaimodels - and freqtrade will pick them up from there based on the provided --freqaimodel name - which has to correspond to the class name of your custom model. Make sure to use unique names to avoid overriding built-in models.

Setting model targets

Regressors

If you are using a regressor, you need to specify a target that has continuous values. FreqAI includes a variety of regressors, such as the CatboostRegressorvia the flag --freqaimodel CatboostRegressor. An example of how you could set a regression target for predicting the price 100 candles into the future would be

df['&s-close_price'] = df['close'].shift(-100)

If you want to predict multiple targets, you need to define multiple labels using the same syntax as shown above.

Classifiers

If you are using a classifier, you need to specify a target that has discrete values. FreqAI includes a variety of classifiers, such as the CatboostClassifier via the flag --freqaimodel CatboostClassifier. If you elects to use a classifier, the classes need to be set using strings. For example, if you want to predict if the price 100 candles into the future goes up or down you would set

df['&s-up_or_down'] = np.where( df["close"].shift(-100) > df["close"], 'up', 'down')

If you want to predict multiple targets you must specify all labels in the same label column. You could, for example, add the label same to define where the price was unchanged by setting

df['&s-up_or_down'] = np.where( df["close"].shift(-100) > df["close"], 'up', 'down')
df['&s-up_or_down'] = np.where( df["close"].shift(-100) == df["close"], 'same', df['&s-up_or_down'])

PyTorch Models

Quick start

The easiest way to quickly run a pytorch model is with the following command (for regression task):

freqtrade trade --config config_examples/config_freqai.example.json --strategy FreqaiExampleStrategy --freqaimodel PyTorchMLPRegressor --strategy-path freqtrade/templates 

Structure

Model

You can use any pytorch model. Here is an example of logistic regression model implementation using pytorch (should be used with nn.BCELoss criterion) for classification tasks.

import torch.nn as nn
import torch 

class LogisticRegression(nn.Module):
    def __init__(self, input_size: int):
        super().__init__()
        # Define your layers
        self.linear = nn.Linear(input_size, 1)
        self.activation = nn.Sigmoid()

    def forward(self, x: torch.Tensor) -> torch.Tensor:
        # Define the forward pass
        out = self.linear(x)
        out = self.activation(out)
        return out

Trainer

The PyTorchModelTrainer performs the idiomatic pytorch train loop: Define our model, loss function, and optimizer, and then move them to the appropriate device (GPU or CPU). Inside the loop, we iterate through the batches in the dataloader, move the data to the device, compute the prediction and loss, backpropagate, and update the model parameters using the optimizer.

In addition, the trainer is responsible for the following:

  • saving and loading the model
  • converting the data from pandas.DataFrame to torch.Tensor.

Integration with Freqai module

Like all freqai models, PyTorch models inherit IFreqaiModel. IFreqaiModel declares three abstract methods: train, fit, and predict. we implement these methods in three levels of hierarchy. From top to bottom:

  1. BasePyTorchModel - all BasePyTorch* inherit it. Implements the train method responsible for general data preparation (e.g., data normalization) and calling the fit method. Sets device _type attribute used by children classes. Sets model_type attribute used by the parent class.

  2. BasePyTorch* - Here, the * represents a group of algorithms, such as classifiers or regressors. the predict method is responsible for data preprocessing, predicting, and postprocessing if needed.

  3. PyTorchClassifier / PyTorchRegressor - implements the fit method, responsible for the main train flaw, where we initialize the trainer and model objects.

Full example

Building a PyTorch regressor using MLP (multilayer perceptron) model, MSELoss criterion, and AdamW optimizer.

class PyTorchMLPRegressor(BasePyTorchRegressor):
    def __init__(self, **kwargs) -> None:
        super().__init__(**kwargs)
        config = self.freqai_info.get("model_training_parameters", {})
        self.learning_rate: float = config.get("learning_rate",  3e-4)
        self.model_kwargs: Dict[str, Any] = config.get("model_kwargs",  {})
        self.trainer_kwargs: Dict[str, Any] = config.get("trainer_kwargs",  {})

    def fit(self, data_dictionary: Dict, dk: FreqaiDataKitchen, **kwargs) -> Any:
        n_features = data_dictionary["train_features"].shape[-1]
        model = PyTorchMLPModel(
            input_dim=n_features,
            output_dim=1,
            **self.model_kwargs
        )
        model.to(self.device)
        optimizer = torch.optim.AdamW(model.parameters(), lr=self.learning_rate)
        criterion = torch.nn.MSELoss()
        init_model = self.get_init_model(dk.pair)
        trainer = PyTorchModelTrainer(
            model=model,
            optimizer=optimizer,
            criterion=criterion,
            device=self.device,
            init_model=init_model,
            target_tensor_type=torch.float,
            **self.trainer_kwargs,
        )
        trainer.fit(data_dictionary)
        return trainer

Here we create PyTorchMLPRegressor that implements the fit method. The fit method specifies the training building blocks: model, optimizer, criterion, and trainer. We inherit both BasePyTorchRegressor and BasePyTorchModel (a parent of BasePyTorchRegressor). The former implements the predict method that suits our regression task. The latter implements the train method.