Exemplo n.º 1
0
    def plot_result(self, name='fANOVA', show=True):
        if not os.path.exists(name):
            os.mkdir(name)

        vis = Visualizer(self.evaluator,
                         self.cs,
                         directory=name,
                         y_label=self._get_label(self.scenario.run_obj))
        self.logger.info('Getting Marginals!')
        pbar = tqdm(range(self.to_evaluate),
                    ascii=True,
                    disable=not self.verbose)
        for i in pbar:
            plt.close('all')
            plt.clf()
            param = list(self.evaluated_parameter_importance.keys())[i]
            # Plot once in log, once linear
            for mode in [(True, '_log'), (False, '')]:
                outfile_name = os.path.join(
                    name,
                    param.replace(os.sep, "_") + mode[1] + ".png")
                # The try/except clause is only for back-compatibility with fanova <= 2.0.11
                try:
                    vis.plot_marginal(
                        self.cs.get_idx_by_hyperparameter_name(param),
                        log_scale=mode[0],
                        show=False,
                        incumbents=self.incumbents)
                except TypeError:
                    self.logger.debug(
                        "Plotting incumbents not supported by fanova < 2.0.12")
                    vis.plot_marginal(
                        self.cs.get_idx_by_hyperparameter_name(param),
                        log_scale=mode[0],
                        show=False)
                fig = plt.gcf()
                fig.savefig(outfile_name)
                plt.close('all')
                plt.clf()
            if show:
                plt.show()
            pbar.set_description('Creating fANOVA plot: {: <.30s}'.format(
                outfile_name.split(os.path.sep)[-1]))
        if self.pairwise:
            self.logger.info('Plotting Pairwise-Marginals!')
            most_important_ones = list(
                self.evaluated_parameter_importance.keys(
                ))[:min(self.num_single, self.n_most_imp_pairs)]
            vis.create_most_important_pairwise_marginal_plots(
                most_important_ones)
            try:
                vis.create_most_important_pairwise_marginal_plots(
                    most_important_ones)
            except TypeError as err:
                self.logger.debug(err, exc_info=1)
                self.logger.warning('Could not create pairwise plots!')
            plt.close('all')
Exemplo n.º 2
0
    def __init__(self, data: pd.DataFrame, hp_names, objective, hp_space=None):
        if import_error is not None:
            raise import_error

        x = data[hp_names]
        y = data[objective]

        self.space = hp_space
        self.hp_names = hp_names
        self.fanova = fANOVA(x.values, y.values)
        self.size = len(hp_names)
        self._importance = np.zeros((self.size, self.size))
        self._importance_std = np.zeros_like(self._importance)
        self.vis = Visualizer(self.fanova, Space.from_dict(hp_space).instantiate(), '/tmp', 'objective')
        self.computed = False
Exemplo n.º 3
0
    def _plot_result(fANOVA, configspace, directory, yrange=None):
        os.makedirs(directory, exist_ok=True)
        vis = Visualizer(fANOVA, configspace, directory, y_label='Predictive Accuracy')

        for hp1 in configspace.get_hyperparameters():
            plt.close('all')
            plt.clf()
            param = hp1.name
            outfile_name = os.path.join(directory, param.replace(os.sep, "_") + ".pdf")
            vis.plot_marginal(configspace.get_idx_by_hyperparameter_name(param), show=False)

            x1, x2, _, _ = plt.axis()
            if yrange:
                plt.axis((x1, x2, yrange[0], yrange[1]))
            plt.savefig(outfile_name)

        pass
Exemplo n.º 4
0
    def plot_result(self, name='fANOVA', show=True):
        if not os.path.exists(name):
            os.mkdir(name)

        if self.scenario.run_obj == 'runtime':
            label = 'runtime [sec]'
        elif self.scenario.run_obj == 'quality':
            label = 'cost'
        else:
            label = '%s' % self.scenario.run_obj
        vis = Visualizer(self.evaluator,
                         self.cs,
                         directory=name,
                         y_label=label)
        self.logger.info('Getting Marginals!')
        pbar = tqdm(range(self.to_evaluate),
                    ascii=True,
                    disable=not self.verbose)
        for i in pbar:
            plt.close('all')
            plt.clf()
            param = list(self.evaluated_parameter_importance.keys())[i]
            outfile_name = os.path.join(name,
                                        param.replace(os.sep, "_") + ".png")
            vis.plot_marginal(self.cs.get_idx_by_hyperparameter_name(param),
                              log_scale=False,
                              show=False)
            fig = plt.gcf()
            fig.savefig(outfile_name)
            plt.close('all')
            plt.clf()
            outfile_name = os.path.join(
                name,
                param.replace(os.sep, "_") + "_log.png")
            vis.plot_marginal(self.cs.get_idx_by_hyperparameter_name(param),
                              log_scale=True,
                              show=False)
            fig = plt.gcf()
            fig.savefig(outfile_name)
            plt.close('all')
            plt.clf()
            if show:
                plt.show()
            pbar.set_description('Creating fANOVA plot: {: <.30s}'.format(
                outfile_name.split(os.path.sep)[-1]))
        if self.pairwise:
            self.logger.info('Plotting Pairwise-Marginals!')
            most_important_ones = list(
                self.evaluated_parameter_importance.keys(
                ))[:min(self.num_single, self.n_most_imp_pairs)]
            try:
                vis.create_most_important_pairwise_marginal_plots(
                    most_important_ones)
            except TypeError:
                self.logger.warning('Could not create pairwise plots!')
            plt.close('all')
Exemplo n.º 5
0
    def _plot_result(fANOVA, configspace, directory, yrange=None):
        vis = Visualizer(fANOVA, configspace)

        try:
            os.makedirs(directory)
        except FileExistsError:
            pass

        for hp in configspace.get_hyperparameters():
            plt.close('all')
            plt.clf()
            param = hp.name
            outfile_name = os.path.join(directory,
                                        param.replace(os.sep, "_") + ".pdf")
            if isinstance(hp, (CategoricalHyperparameter)):
                vis.plot_categorical_marginal(
                    configspace.get_idx_by_hyperparameter_name(param),
                    show=False,
                    ylabel='Predictive Accuracy')
            else:
                vis.plot_marginal(
                    configspace.get_idx_by_hyperparameter_name(param),
                    resolution=100,
                    show=False,
                    ylabel='Predictive Accuracy')
            x1, x2, _, _ = plt.axis()
            if yrange:
                plt.axis((x1, x2, yrange[0], yrange[1]))
            plt.savefig(outfile_name)
        pass
Exemplo n.º 6
0
 def plot_result(self, name='fANOVA'):
     vis = Visualizer(self.evaluator, self.cs)
     if not os.path.exists(name):
         os.mkdir(name)
     self.logger.info('Getting Marginals!')
     for i in range(self.to_evaluate):
         plt.close('all')
         plt.clf()
         param = list(self.evaluated_parameter_importance.keys())[i]
         outfile_name = os.path.join(name,
                                     param.replace(os.sep, "_") + ".png")
         if isinstance(self.cs.get_hyperparameter(param),
                       (CategoricalHyperparameter)):
             vis.plot_categorical_marginal(
                 self.cs.get_idx_by_hyperparameter_name(param), show=False)
         else:
             vis.plot_marginal(
                 self.cs.get_idx_by_hyperparameter_name(param), show=False)
         plt.savefig(outfile_name)
         self.logger.info('Creating fANOVA plot: %s' % outfile_name)
     self.logger.info('Getting Pairwise-Marginals!')
     self.logger.info('This will take some time!')
     vis.create_most_important_pairwise_marginal_plots(
         name, self.to_evaluate)
Exemplo n.º 7
0
 def plot_result(self, name='fANOVA', show=True):
     if not os.path.exists(name):
         os.mkdir(name)
     vis = Visualizer(self.evaluator, self.cs, directory=name)
     self.logger.info('Getting Marginals!')
     for i in range(self.to_evaluate):
         plt.close('all')
         plt.clf()
         param = list(self.evaluated_parameter_importance.keys())[i]
         outfile_name = os.path.join(name,
                                     param.replace(os.sep, "_") + ".png")
         vis.plot_marginal(self.cs.get_idx_by_hyperparameter_name(param),
                           show=False)
         fig = plt.gcf()
         fig.savefig(outfile_name)
         if show:
             plt.show()
         self.logger.info('Creating fANOVA plot: %s' % outfile_name)
     self.logger.info('Plotting Pairwise-Marginals!')
     most_important_ones = list(self.evaluated_parameter_importance.keys(
     ))[:min(self.num_single, self.n_most_imp_pairs)]
     vis.create_most_important_pairwise_marginal_plots(most_important_ones)
     plt.close('all')
Exemplo n.º 8
0
def run(args):
    root = logging.getLogger()
    root.setLevel(logging.INFO)
    
    with open(args.dataset_path, 'r') as fp:
        arff_dataset = arff.load(fp)
    config_space = sklearnbot.config_spaces.get_config_space(args.classifier, None)
    data = openmlcontrib.meta.arff_to_dataframe(arff_dataset, config_space)
    data = openmlcontrib.meta.integer_encode_dataframe(data, config_space)
    meta_data = get_dataset_metadata(args.dataset_path)
    if args.measure not in data.columns.values:
        raise ValueError('Could not find measure in dataset: %s' % args.measure)
    if set(config_space.get_hyperparameter_names()) != set(meta_data['col_parameters']):
        missing_cs = set(meta_data['col_parameters']) - set(config_space.get_hyperparameter_names())
        missing_ds = set(config_space.get_hyperparameter_names()) - set(meta_data['col_parameters'])
        raise ValueError('ConfigSpace and hyperparameters of dataset do not '
                         'align. ConfigSpace misses: %s, dataset misses: %s' % (missing_cs, missing_ds))
    task_ids = data['task_id'].unique()

    result = list()
    for idx, task_id in enumerate(task_ids):
        logging.info('Running fanova on task %d (%d/%d)' % (task_id, idx + 1, len(task_ids)))
        data_task = data[data['task_id'] == task_id]
        
        evaluator = fanova.fanova.fANOVA(X=data_task[config_space.get_hyperparameter_names()].values,
                                         Y=data_task[args.measure].values,
                                         config_space=config_space,
                                         n_trees=args.n_trees)

        os.makedirs(args.output_directory, exist_ok=True)

        vis = Visualizer(evaluator, config_space, args.output_directory, y_label='Predictive Accuracy')
        indices = list(range(len(config_space.get_hyperparameters())))
        for comb_size in range(1, args.comb_size + 1):
            for idx in itertools.combinations(indices, comb_size):
                param_names = np.array(config_space.get_hyperparameter_names())[np.array(idx)]
                logging.info('-- Calculating marginal for %s' % param_names)
                importance = evaluator.quantify_importance(idx)[idx]
                if comb_size == 1:
                    visualizer_res = vis.generate_marginal(idx[0], args.resolution)
                    # visualizer returns mean, std and potentially grid
                    avg_marginal = np.array(visualizer_res[0])
                elif comb_size == 2:
                    visualizer_res = vis.generate_pairwise_marginal(idx, args.resolution)
                    # visualizer returns grid names and values
                    avg_marginal = np.array(visualizer_res[1])
                else:
                    raise ValueError('No support yet for higher dimensions than 2. Got: %d' % comb_size)
                difference_max_min = max(avg_marginal.reshape((-1,))) - min(avg_marginal.reshape((-1,)))

                current = {
                    'task_id': task_id,
                    'hyperparameter': ' / '.join(param_names),
                    'n_hyperparameters': len(param_names),
                    'importance_variance': importance['individual importance'],
                    'importance_max_min': difference_max_min,
                }
                
                result.append(current)
    df_result = pd.DataFrame(result)
    result_path = os.path.join(args.output_directory, 'fanova_%s_depth_%d.csv' % (args.classifier, args.comb_size))
    df_result.to_csv(result_path)
    logging.info('resulting csv: %s' % result_path)
    logging.info('To plot, run <openml_pimp_root>/examples/plot/plot_fanova.py')
Exemplo n.º 9
0
    def plot_bokeh(self, plot_name=None, show_plot=False, plot_pairwise="most_important"):
        """
        Plot single and pairwise margins in bokeh-plot. Single margins are always plotted (not expensive), pairwise can
        be configured by argument.

        Parameters
        ----------
        plot_name: str
            path where to store the plot, None to not save it
        show_plot: bool
            whether or not to open plot in standard browser
        plot_pairwise: str
            choose from ["none", "most_important", "all"] where "most_important" relies on the fanova module to decide
            what that means

        Returns
        -------
        layout: bokeh.models.Column
            bokeh plot (can be used in notebook or comparted with components)
        """
        vis = Visualizer(self.evaluator, self.cs, directory='.', y_label=self._get_label(self.scenario.run_obj))

        ####################
        # Single marginals #
        ####################
        plots_single = []
        params = list(self.evaluated_parameter_importance.keys())
        pbar = tqdm(deepcopy(params), ascii=True, disable=not self.verbose)
        for param_name in pbar:
            # Try and except pairwise importances that are also saved in evaluated_parameter_importance...
            try:
                param = self.cs.get_hyperparameter(param_name)
            except KeyError as err:
                self.logger.debug(err, exc_info=1)
                continue

            pbar.set_description('Plotting fANOVA (in bokeh) for %s' % param_name)

            incumbents = []
            if not self.incumbents is None:
                incumbents = self.incumbents.copy() if isinstance(self.incumbents, list) else [self.incumbents]
            values = [c[param_name] for c in incumbents if param_name in c and c[param_name] is not None]

            if isinstance(param, (CategoricalHyperparameter, Constant)):
                labels = param.choices if isinstance(param, CategoricalHyperparameter) else str(param)
                mean, std = vis.generate_marginal(param_name)
                inc_indices = [labels.index(val) for val in values]

                p = bokeh_boxplot(labels, mean, std,
                                  x_label=param.name,
                                  y_label="runtime [sec]" if self.scenario.run_obj == "runtime" else "cost",
                                  runtime=self.scenario.run_obj=="runtime",
                                  inc_indices=inc_indices)

            else:
                mean, std, grid = vis.generate_marginal(param_name, 100)
                mean, std = np.asarray(mean), np.asarray(std)
                log_scale = param.log or (np.diff(grid).std() > 0.000001)
                inc_indices = [(np.abs(np.asarray(grid) - val)).argmin() for val in values]

                p = bokeh_line_uncertainty(grid, mean, std, log_scale,
                                           x_label=param.name,
                                           y_label="runtime [sec]" if self.scenario.run_obj == "runtime" else "cost",
                                           inc_indices=inc_indices)

            plots_single.append(Panel(child=Row(p), title=param_name))

        ######################
        # Pairwise marginals #
        ######################
        if plot_pairwise == "all":
            combis = list(it.combinations(self.cs.get_hyperparameters(), 2))
        elif plot_pairwise == "most_important":
            most_important_ones = list(self.evaluated_parameter_importance.keys())[
                                  :min(self.num_single, self.n_most_imp_pairs)]
            most_important_pairwise_marginals = vis.fanova.get_most_important_pairwise_marginals(
                                                params=most_important_ones)
            combis = [(self.cs.get_hyperparameter(name1), self.cs.get_hyperparameter(name2)) for name1, name2 in
                      most_important_pairwise_marginals]
        elif plot_pairwise == "none":
            combis = []
        else:
            raise ValueError("{} not a valid set of pairwise plots to generate...".format(plot_pairwise))

        plots_pairwise = []
        pbar = tqdm(deepcopy(combis), ascii=True, disable=not self.verbose)
        for p1, p2 in pbar:
            pbar.set_description('Plotting pairwise fANOVA (in bokeh) for %s & %s' % (p1.name, p2.name))
            first_is_cat = isinstance(p1, CategoricalHyperparameter)
            second_is_cat = isinstance(p2, CategoricalHyperparameter)
            # There are essentially three cases / different plots:
            # First case: both categorical -> heatmap
            if first_is_cat or second_is_cat:
                choices, zz = vis.generate_pairwise_marginal((p1.name, p2.name), 20)
                # Working with pandas makes life easier
                data = pd.DataFrame(zz, index=choices[0], columns=choices[1])
                # Setting names for rows and columns and make categoricals strings
                data.index.name, data.columns.name = p1.name, p2.name
                data.index = data.index.astype(str) if first_is_cat else data.index
                data.columns = data.columns.astype(str) if second_is_cat else data.columns
                if first_is_cat and second_is_cat:
                    p = bokeh_heatmap_cat(data, p1.name, p2.name)
                else:
                    # Only one of them is categorical -> create multi-line-plot
                    cat_choices = p1.choices if first_is_cat else p2.choices
                    # We want categorical values be represented by columns:
                    if not second_is_cat:
                        data = data.transpose()
                    # Find y_min and y_max BEFORE resetting index (otherwise index max obscure the query)
                    y_limits = (data.min().min(), data.max().max())
                    x_limits = (p1.lower if second_is_cat else p2.lower, p1.upper if second_is_cat else p2.upper)
                    # We want the index as a column (for plotting on x-axis)
                    data = data.reset_index()
                    p = bokeh_multiline(data, x_limits, y_limits,
                                        p1.name if second_is_cat else p2.name,
                                        cat_choices,
                                        y_label="runtime [sec]" if self.scenario.run_obj == "runtime" else "cost",
                                        z_label=p1.name if first_is_cat else p2.name,
                                        )

            else:
                # Third case: both continous
                grid, zz = vis.generate_pairwise_marginal((p1.name, p2.name), 20)
                data = pd.DataFrame(zz, index=grid[0], columns=grid[1])
                data.index.name, data.columns.name = p1.name, p2.name
                p = bokeh_heatmap_num(data, p1.name, p2.name, p1.log, p2.log)

            plots_pairwise.append(Panel(child=Row(p), title=" & ".join([p1.name, p2.name])))

        # Putting both together
        tabs_single = Tabs(tabs=[*plots_single])
        if len(plots_pairwise) > 0:
            tabs_pairwise = Tabs(tabs=[*plots_pairwise])
            layout = Column(tabs_single, tabs_pairwise)
        else:
            layout = Column(tabs_single)

        # Save and show...
        save_and_show(plot_name, show_plot, layout)

        return layout
Exemplo n.º 10
0
    def execute(save_folder, runhistory_location, configspace_location, manual_logtransform, use_percentiles, interaction_effect, n_trees, run_limit=None, draw_plots=True):
        with open(runhistory_location) as runhistory_file:
            runhistory = json.load(runhistory_file)
        with open(configspace_location) as configspace_file:
            configspace = read(configspace_file)
        os.makedirs(save_folder, exist_ok=True)

        X = []
        y = []

        for item in runhistory['data']:
            if run_limit is not None and len(X) > run_limit:
                break

            valid = True
            current = []
            setup_id = str(item[0][0])
            configuration = runhistory['configs'][setup_id]
            for param in configspace.get_hyperparameters():
                value = configuration[param.name]
                if isinstance(param, ConfigSpace.hyperparameters.UniformFloatHyperparameter) and not isinstance(value, float):
                    valid = False
                elif isinstance(param, ConfigSpace.hyperparameters.UniformIntegerHyperparameter) and not isinstance(value, int):
                    valid = False

                if isinstance(param, ConfigSpace.hyperparameters.CategoricalHyperparameter):
                    value = param.choices.index(value)
                elif param.log and manual_logtransform:
                    value = np.log(value)

                current.append(value)
            if valid:
                X.append(current)
                y.append(item[1][0])
            else:
                print('Illegal configuration', current)
        X = np.array(X)
        y = np.array(y)

        if X.ndim != 2:
            raise ValueError('Wrong shape')

        if manual_logtransform:
            configspace = openmlpimp.utils.scale_configspace_to_log(configspace)

        cutoffs = (-np.inf, np.inf)
        if use_percentiles:
            p75 = np.percentile(y, 75.0)
            p100 = np.percentile(y, 100.0)
            cutoffs = (p75, p100)

        # start the evaluator
        evaluator = fanova_pyrfr(X=X, Y=y, config_space=configspace, config_on_hypercube=False, cutoffs=cutoffs, n_trees=n_trees)
        # obtain the results
        params = configspace.get_hyperparameters()
        result = {}

        for idx, param in enumerate(params):
            importance = evaluator.quantify_importance([idx])[(idx,)]['total importance']
            result[param.name] = importance

        # store main results to disk
        filename = 'pimp_values_fanova.json'
        with open(os.path.join(save_folder, filename), 'w') as out_file:
            json.dump(result, out_file, sort_keys=True, indent=4, separators=(',', ': '))
            print('Saved individuals to %s' %os.path.join(save_folder, filename))

        # call plotting fn
        yrange = (0, 1)
        if use_percentiles:
            yrange = (p75, p100)
        if draw_plots:
            FanovaBackend._plot_result(evaluator, configspace, save_folder + '/fanova', yrange)

        if interaction_effect:
            result_interaction = {}
            for idx, param in enumerate(params):
                for idx2, param2 in enumerate(params):
                    if param.name >= param2.name: # string comparison cause stable
                        continue
                    print('interaction effects between', param.name, param2.name)
                    interaction = evaluator.quantify_importance([idx, idx2])[(idx,idx2)]['total importance']
                    interaction -= result[param.name]
                    interaction -= result[param2.name]
                    combined_name = param.name + '__' + param2.name
                    if interaction < 0.0:
                        raise ValueError('interaction score too low. Params: %s score %d' %(combined_name, interaction))
                    result_interaction[combined_name] = interaction

            for idx, param in enumerate(params):
                for idx2, param2 in enumerate(params):
                    if param.name >= param2.name:  # string comparison cause stable
                        continue
                    for idx3, param3 in enumerate(params):
                        if param2.name >= param3.name:  # string comparison cause stable
                            continue

                        print('interaction effects between', param.name, param2.name, param3.name)
                        interaction = evaluator.quantify_importance([idx, idx2, idx3])[(idx, idx2, idx3)]['total importance']
                        interaction -= result[param.name]
                        interaction -= result[param2.name]
                        interaction -= result[param3.name]
                        combined_name = param.name + '__' + param2.name + '__' + param3.name

                        interaction -= result_interaction[param.name + '__' + param2.name]
                        interaction -= result_interaction[param2.name + '__' + param3.name]
                        interaction -= result_interaction[param.name + '__' + param3.name]

                        if interaction < 0.0:
                            raise ValueError('interaction score too low. Params: %s score %d' % (combined_name, interaction))
                        result_interaction[combined_name] = interaction

            # store interaction effects to disk

            if sum(result_interaction.values()) + sum(result.values()) > 1:
                raise ValueError('Sum of results too high')

            filename = 'pimp_values_fanova_interaction.json'
            with open(os.path.join(save_folder, filename), 'w') as out_file:
                json.dump(result_interaction, out_file, sort_keys=True, indent=4, separators=(',', ': '))
                print('Saved interactions to %s' %os.path.join(save_folder, filename))
            if draw_plots:
                vis = Visualizer(evaluator, configspace, save_folder + '/fanova', y_label='Predictive Accuracy')
                vis.create_most_important_pairwise_marginal_plots()

        return save_folder + "/" + filename
Exemplo n.º 11
0
class FANOVA:
    """
    Parameters
    ----------
    data: DataFrame

    hp_names: List[str]
        list of hyper parameter names (to extract from the DataFrame)

    objective: str
        name of the objective

    References
    ----------
    .. [1] F. Hutter and H. Hoos and K. Leyton-Brown
        "An Efficient Approach for Assessing Hyperparameter Importance"
        Proceedings of International Conference on Machine Learning 2014 (ICML 2014).
    """

    def __init__(self, data: pd.DataFrame, hp_names, objective, hp_space=None):
        if import_error is not None:
            raise import_error

        x = data[hp_names]
        y = data[objective]

        self.space = hp_space
        self.hp_names = hp_names
        self.fanova = fANOVA(x.values, y.values)
        self.size = len(hp_names)
        self._importance = np.zeros((self.size, self.size))
        self._importance_std = np.zeros_like(self._importance)
        self.vis = Visualizer(self.fanova, Space.from_dict(hp_space).instantiate(), '/tmp', 'objective')
        self.computed = False

    def _gen(self):
        if not self.computed:
            self._compute_importance()
            self.computed = True

    def compute_marginal(self, index, marginals=None):
        """Compute the effect a change on the hyper parameter value has on the objective value

        Returns
        -------
        returns a list of dictionaries (name, objective, value, std)
        """
        data = self.vis.generate_marginal(index, resolution=100)
        marginals = select(marginals, [])

        # (mean, std, grid)
        if len(data) > 2:
            for y, std, x in zip(data[0], data[1], data[2]):
                marginals.append(dict(
                    name=self.hp_names[index],
                    objective=y,
                    value=x,
                    std=std))
        # (mean, std)
        else:   # Categorical
            choices = self._get_choices(index)

            for (y, std), x in zip(data, choices):
                marginals.append(dict(
                    name=self.hp_names[index],
                    objective=y,
                    value=x,
                    std=std))

        return marginals

    def _get_choices(self, param):
        """For categorical HP retrieve the choices available"""
        from ConfigSpace import CategoricalHyperparameter
        p, p_name, p_idx = self.vis._get_parameter(param)

        if isinstance(p, CategoricalHyperparameter):
            return p.choices

        return ['Constant']

    def compute_marginals(self):
        marginals = []

        for i, _ in enumerate(self.hp_names):
            self.compute_marginal(i, marginals)

        return marginals

    @property
    def importance(self):
        """TODO: doc

        Returns
        -------
        Importance matrix of pairs of hyper parameters
        """
        self._gen()
        return self._importance

    @property
    def importance_std(self):
        """TODO: doc

        Returns
        -------
        Standard deviation of the importance matrix of pairs of hyper parameters
        """
        self._gen()
        return self._importance_std

    @property
    def importance_long(self):
        self._gen()
        return self._importance_long

    def _compute_importance(self):
        importance = self.fanova.quantify_importance(list(range(self.size )))
        self._importance_long = []

        for k, values in importance.items():
            if len(k) == 1:
                i = k[0]
                j = k[0]
            elif len(k) == 2:
                i = k[0]
                j = k[1]
            else:
                continue

            self._importance[i, j] = values['total importance']
            self._importance_std[i, j] = values['total std']
            self._importance_long.append(dict(
                row=self.hp_names[i],
                col=self.hp_names[j],
                importance=values['total importance'],
                std=values['total std']
            ))