Exemple #1
0
    def __init__(self):

        self.es_loader = EntitySetLoader()
        self.featurization = Featurization()
        self.modeler = Modeler()

        self.es = None
        self.chosen_problem = None
        self.target_entity = None
Exemple #2
0
def es_loader():
    return EntitySetLoader()
Exemple #3
0
class Cardea():
    """An interface class that ties the end-to-end system together.

    Attributes:
        es_loader: An entityset loader.
        featurization: A featurization class.
        modeler: A modeling class.
        problems: A list of currently available prediction problems.
        chosen_problem: The selected prediction problem or regression.
        es: The loaded entityset.
        target_entity: The target entity for featurization.
    """
    def __init__(self):

        self.es_loader = EntitySetLoader()
        self.featurization = Featurization()
        self.modeler = Modeler()

        self.es = None
        self.chosen_problem = None
        self.target_entity = None

    def load_data_entityset(self, folder_path=None):
        """Returns an entityset loaded with .csv files in folder_path.

        Load the given dataset within the folder path into an entityset. The dataset
        must be in a FHIR structure format. If no folder_path is not passed, the
        function will automatically load kaggle's missed appointment dataset.

        Args:
            folder_path: A directory of all .csv files that should be loaded.

        Returns:
            An entityset with loaded data.
        """

        if folder_path:
            self.es = self.es_loader.load_data_entityset(folder_path)

        else:
            csv_s3 = "https://s3.amazonaws.com/dai-cardea/"
            kaggle = [
                'Address', 'Appointment_Participant', 'Appointment',
                'CodeableConcept', 'Coding', 'Identifier', 'Observation',
                'Patient', 'Reference'
            ]

            fhir = {
                resource: pd.read_csv(csv_s3 + resource + ".csv")
                for resource in kaggle
            }
            self.es = self.es_loader.load_df_entityset(fhir)

    def list_problems(self):
        """Returns a list of the currently available problems.

        Returns:
            A set of the available problems.
        """

        problems = set([])
        for attribute_string in dir(cardea.problem_definition):
            attribute = getattr(cardea.problem_definition, attribute_string)
            if isclass(attribute):
                if attribute.__name__ and attribute.__name__ != 'ProblemDefinition':
                    problems.add(attribute.__name__)

        return problems

    def select_problem(self, selection, parameter=None):
        """Select a prediction problem and extract information.

        Update the select_problem attribute and generate the cutoff times,
        the target entity and update the entityset.

        Args:
            selection: Name of the chosen prediction problem.
            data: Entityset representation of the data.
            parameters: A variable to change the default parameters, if any.

        Returns:
            The updated version of the entityset and cutoff time label.
        """

        # problem selection
        if selection == 'LengthOfStay':
            self.chosen_problem = LengthOfStay()

        elif selection == 'MortalityPrediction':
            self.chosen_problem = MortalityPrediction()

        elif selection == 'MissedAppointmentProblemDefinition':
            self.chosen_problem = MissedAppointmentProblemDefinition()

        elif selection == 'ProlongedLengthOfStay' and parameter:
            self.chosen_problem = ProlongedLengthOfStay(parameter)

        elif selection == 'ProlongedLengthOfStay':
            self.chosen_problem = ProlongedLengthOfStay()

        elif selection == 'Readmission' and parameter:
            self.chosen_problem = Readmission(parameter)

        elif selection == 'Readmission':
            self.chosen_problem = Readmission()

        elif selection == 'DiagnosisPrediction' and parameter:
            self.chosen_problem = DiagnosisPrediction(parameter)

        elif selection == 'DiagnosisPrediction':
            raise ValueError('unspecified diagnosis code')

        else:
            raise ValueError('{} is not a defined problem'.format(selection))

        # target label calculation
        self.es, self.target_entity, cutoff = self.chosen_problem.generate_cutoff_times(
            self.es)
        return cutoff

    def list_feature_primitives(self):
        """Returns built-in primitive in Featuretools.

        Returns:
            A pandas dataframe that lists and describes each built-in primitives.
        """
        return ft.list_primitives()

    def generate_features(self, cutoff):
        """Returns a the calculated feature matrix.

        Args:
            es: A featuretools entityset that holds data.
            cutoff: A pandas dataframe that indicates cutoff_time for each instance.

        Returns:
            Encoded feature_matrix, encoded features.
        """

        fm_encoded, _ = self.featurization.generate_feature_matrix(
            self.es, self.target_entity, cutoff)
        fm_encoded = fm_encoded.reset_index(drop=True)
        return fm_encoded

    def execute_model(self,
                      feature_matrix,
                      target,
                      primitives,
                      optimize=False,
                      hyperparameters=None):
        """Executes and predict all the pipelines.

        This method executes the given pipeline and returns a list for all the pipelines
        with the result of each fold with its associated predicted values and actual values.

        Args:
            data_frame: A dataframe, which encapsulates all the records of that entity.
            primitives_list: A list of the primitives within a pipeline.
            optimize: A boolean value which indicates whether to optimize the model or not.
            hyperparameters: A dictionary of hyperparameters for each primitives.

        Returns:
            A list for all the executed pipelines and its result.
        """

        return self.modeler.execute_pipeline(
            data_frame=feature_matrix,
            target=target,
            primitives_list=primitives,
            problem_type=self.chosen_problem.prediction_type,
            optimize=False,
            hyperparameters=None)

    def convert_to_json(dic):
        """Converts a given dictionary to json format.

        Args:
            dict: A dictionary of values to be coverted.

        Returns:
            A string in json format.
        """
        return json.dumps(dic)

    def convert_from_json(string):
        """Converts a given json string to dictionary format.

        Args:
            json: A dictionary of values to be coverted.

        Returns:
            A parsed dictionary.
        """
        return json.loads(string)
Exemple #4
0
class Cardea():
    """An interface class that ties the end-to-end system together.

    Args:
        es_loader (EntitySetLoader):
            An entityset loader.
        featurization (Featurization):
            A featurization class.
        modeler (Modeler):
            A modeling class.
        problems (list):
            A list of currently available prediction problems.
        chosen_problem (str):
            The selected prediction problem or regression.
        es (featuretools.EntitySet):
            The loaded entityset.
        target_entity (str):
            The target entity for featurization.
    """

    def __init__(self):

        self.es_loader = EntitySetLoader()
        self.featurization = Featurization()

        self.es = None
        self.chosen_problem = None
        self.target_entity = None
        self.modeler = None

    def load_entityset(self, data, fhir=True):
        """Returns an entityset loaded with .csv files in data.

        Load the given dataset into an entityset. The dataset
        must be in FHIR or MIMIC structure format.

        Args:
            data (str):
                A directory of all .csv files that should be loaded. To load demo dataset,
                pass the name of the dataset "kaggle" or "mimic".
            fhir (bool):
                An indicator of whether to use FHIR or MIMIC schema.

        Returns:
            featuretools.EntitySet:
                An entityset with loaded data.
        """
        demo = ['kaggle', 'mimic']
        if not os.path.exists(data) and data in demo:
            data = self.download_demo(data)

        if fhir:
            self.es = self.es_loader.load_data_entityset(data)
        else:
            self.es = load_mimic_data(data)

    @staticmethod
    def download_demo(name, data_path=DATA_PATH):
        data_path = os.path.join(data_path, name)
        os.makedirs(data_path, exist_ok=True)

        url = S3_URL.format(BUCKET, '{}.zip'.format(name))
        compressed = ZipFile(BytesIO(urlopen(url).read()))

        LOGGER.info('Downloading dataset %s from %s', name, url)
        for file in compressed.namelist():
            filename = os.path.join(data_path, file)
            csv_file = compressed.open(file)

            data = pd.read_csv(csv_file, dtype=str)
            data.to_csv(filename, index=False)

        return data_path

    def list_problems(self):
        """Returns a list of the currently available problems.

        Returns:
            list:
                A list of the available problems.
        """

        problems = set([])
        for attribute_string in dir(cardea.problem_definition):
            attribute = getattr(cardea.problem_definition, attribute_string)
            if isclass(attribute):
                if attribute.__name__ and attribute.__name__ != 'ProblemDefinition':
                    problems.add(attribute.__name__)

        return problems

    def select_problem(self, selection, parameter=None):
        """Select a prediction problem and extract information.

        Update the select_problem attribute and generate the cutoff times,
        the target entity and update the entityset.

        Args:
            selection (str):
                Name of the chosen prediction problem.
            parameters (dict):
                Variables to change the default parameters, if any.

        Returns:
            featuretools.EntitySet, str, pandas.DataFrame:
                * An updated EntitySet if a new column is generated.
                * A string indicating the selected target entity.
                * A dataframe of cutoff times and their target labels.
        """
        LOGGER.info("Selecting %s prediction problem", selection)

        # problem selection
        if selection == 'LengthOfStay':
            self.chosen_problem = LengthOfStay()

        elif selection == 'MortalityPrediction':
            self.chosen_problem = MortalityPrediction()

        elif selection == 'MissedAppointment':
            self.chosen_problem = MissedAppointment()

        elif selection == 'ProlongedLengthOfStay' and parameter:
            self.chosen_problem = ProlongedLengthOfStay(parameter)

        elif selection == 'ProlongedLengthOfStay':
            self.chosen_problem = ProlongedLengthOfStay()

        elif selection == 'Readmission' and parameter:
            self.chosen_problem = Readmission(parameter)

        elif selection == 'Readmission':
            self.chosen_problem = Readmission()

        elif selection == 'DiagnosisPrediction' and parameter:
            self.chosen_problem = DiagnosisPrediction(parameter)

        elif selection == 'DiagnosisPrediction':
            raise ValueError('unspecified diagnosis code')

        else:
            raise ValueError('{} is not a defined problem'.format(selection))

        # target label calculation
        self.es, self.target_entity, cutoff = self.chosen_problem.generate_cutoff_times(self.es)

        # set default pipeline
        if self.chosen_problem.prediction_type == "classification":
            pipeline = "Random Forest"
        else:
            pipeline = "Random Forest Regressor"

        self.modeler = Modeler(pipeline, self.chosen_problem.prediction_type)

        return cutoff

    def list_feature_primitives(self):
        """Returns built-in primitive in Featuretools.

        Returns:
            pandas.DataFrame:
                A dataframe that lists and describes each built-in primitives.
        """
        return ft.list_primitives()

    def generate_features(self, cutoff):
        """Returns a the calculated feature matrix.

        Args:
            es (featuretools.EntitySet):
                An entityset that holds data.
            cutoff (pandas.DataFrame):
                A dataframe that indicates cutoff time for each instance.

        Returns:
            pandas.DataFrame, list:
              * The generated feature matrix.
              * List of feature definitions in the feature matrix.
        """

        fm_encoded, _ = self.featurization.generate_feature_matrix(
            self.es, self.target_entity, cutoff)
        fm_encoded = fm_encoded.reset_index(drop=True)
        return fm_encoded

    def select_pipeline(self, pipeline):
        """Select a pipeline.

        Args:
            pipeline (MLPipeline or str):
                A pipeline instance or the name/path of a pipeline.
        """
        LOGGER.info("Selecting %s pipeline", pipeline)
        self.modeler = Modeler(pipeline, self.chosen_problem.prediction_type)

    def train_test_split(self, X, y, test_size, shuffle):
        """Split the training dataset and the testing dataset.

        Args:
            X (pandas.DataFrame or ndarray):
                Inputs to the pipeline.
            y (pandas.Series or ndarray):
                Target values.
            test_size (float):
                The proportion of the dataset to include in the test dataset.
            shuffle (bool):
                Whether or not to shuffle the data before splitting.

        Returns:
            list:
                List containing the train-test split of the inputs and targets.
        """
        return self.modeler.train_test_split(X, y, test_size, shuffle)

    def fit(self, X, y, tune=False, max_evals=10, scoring=None, verbose=False):
        """Train the cardea pipeline.

        Args:
            X (pandas.DataFrame or ndarray):
                Inputs to the pipeline.
            y (pandas.Series ndarray):
                Target values.
            tune (bool):
                Whether to optimize hyper-parameters of the pipelines.
            max_evals (int):
                Maximum number of hyper-parameter optimization iterations.
            scoring (str):
                The name of the scoring function used in the hyper-parameter optimization.
            verbose (bool):
                Whether to log information during processing.
        """
        self.modeler.fit(X, y, tune, max_evals, scoring, verbose)

    def predict(self, X):
        """Get predictions from the cardea pipeline.

        Args:
            X (pandas.DataFrame or ndarray):
                Inputs to the pipeline.

        Returns:
            ndarray:
                Predictions to the input data.
        """
        return self.modeler.predict(X)

    def fit_predict(self, X, y, tune=False, max_evals=10, scoring=None, verbose=False):
        """Train a cardea pipeline then make predictions.

        Args:
            X (pandas.DataFrame or ndarray):
                Inputs to the pipeline.
            y (pandas.Series or ndarray):
                Target values.
            tune (bool):
                Whether to optimize hyper-parameters of the pipelines.
            max_evals (int):
                Maximum number of hyper-parameter optimization iterations.
            scoring (str):
                The name of the scoring function used in the hyper-parameter optimization.
            verbose (bool):
                Whether to log information during processing.

        Returns:
            ndarray:
                Predictions to the input data.
        """
        return self.modeler.fit_predict(X, y, tune, max_evals, scoring, verbose)

    def evaluate(self, X, y, test_size=0.2, shuffle=True, tune=False, max_evals=10, scoring=None,
                 metrics=None, verbose=False):
        """Evaluate the cardea pipeline.

        Args:
            X (pandas.DataFrame or ndarray):
                Inputs to the pipeline.
            y (pandas.Series or ndarray):
                Target values.
            test_size (float):
                The proportion of the dataset to include in the test dataset.
            shuffle (bool):
                Whether or not to shuffle the data before splitting.
            tune (bool):
                Whether to optimize hyper-parameters of the pipelines.
            max_evals (int):
                Maximum number of hyper-parameter optimization iterations.
            scoring (str):
                The name of the scoring function used in the hyper-parameter optimization.
            metrics (list):
                A list of scoring function names. The scoring functions should be consistent
                with the problem type.
            verbose (bool):
                Whether to log information during processing.
        """
        return self.modeler.evaluate(
            X, y, test_size, shuffle, tune, max_evals, scoring, metrics, verbose)

    def save(self, path):
        """Save this object using pickle.

        Args:
            path (str):
                Path to the file where the serialization of
                this object will be stored.
        """
        os.makedirs(os.path.dirname(path), exist_ok=True)
        with open(path, 'wb') as pickle_file:
            pickle.dump(self, pickle_file)

    @classmethod
    def load(cls, path: str):
        """Load an Orion instance from a pickle file.

        Args:
            path (str):
                Path to the file where the instance has been
                previously serialized.

        Returns:
            Cardea:
                A Cardea instance

        Raises:
            ValueError:
                If the serialized object is not an Cardea instance.
        """
        with open(path, 'rb') as pickle_file:
            cardea = pickle.load(pickle_file)
            if not isinstance(cardea, cls):
                raise ValueError('Serialized object is not a Cardea instance')

            return cardea