def model(winequality_vd): model_class = LinearSVR("lsvr_model_test", ) model_class.drop() model_class.fit("public.winequality", ["citric_acid", "residual_sugar", "alcohol"], "quality") yield model_class model_class.drop()
def model(base, winequality_vd): base.cursor.execute("DROP MODEL IF EXISTS lsvr_model_test") model_class = LinearSVR("lsvr_model_test", cursor=base.cursor) model_class.fit("public.winequality", ["citric_acid", "residual_sugar", "alcohol"], "quality") yield model_class model_class.drop()
def test_get_plot(self, winequality_vd): current_cursor().execute("DROP MODEL IF EXISTS model_test_plot") model_test = LinearSVR("model_test_plot", ) model_test.fit("public.winequality", ["alcohol"], "quality") result = model_test.plot() assert len(result.get_default_bbox_extra_artists()) == 9 plt.close("all") model_test.drop()
def test_model_from_vDF(self, base, winequality_vd): base.cursor.execute("DROP MODEL IF EXISTS lsvr_from_vDF") model_test = LinearSVR("lsvr_from_vDF", cursor=base.cursor) model_test.fit(winequality_vd, ["alcohol"], "quality") base.cursor.execute( "SELECT model_name FROM models WHERE model_name = 'lsvr_from_vDF'") assert base.cursor.fetchone()[0] == "lsvr_from_vDF" model_test.drop()
def test_contour(self, winequality_vd): model_test = LinearSVR("model_contour", ) model_test.drop() model_test.fit( winequality_vd, ["citric_acid", "residual_sugar"], "quality", ) result = model_test.contour() assert len(result.get_default_bbox_extra_artists()) == 38 model_test.drop()
def test_set_cursor(self, base): model_test = LinearSVR("lsvr_cursor_test", cursor=base.cursor) # TODO: creat a new cursor model_test.set_cursor(base.cursor) model_test.drop() model_test.fit("public.winequality", ["alcohol"], "quality") base.cursor.execute( "SELECT model_name FROM models WHERE model_name = 'lsvr_cursor_test'" ) assert base.cursor.fetchone()[0] == "lsvr_cursor_test" model_test.drop()
def test_drop(self, base): base.cursor.execute("DROP MODEL IF EXISTS lsvr_model_test_drop") model_test = LinearSVR("lsvr_model_test_drop", cursor=base.cursor) model_test.fit("public.winequality", ["alcohol"], "quality") base.cursor.execute( "SELECT model_name FROM models WHERE model_name = 'lsvr_model_test_drop'" ) assert base.cursor.fetchone()[0] == "lsvr_model_test_drop" model_test.drop() base.cursor.execute( "SELECT model_name FROM models WHERE model_name = 'lsvr_model_test_drop'" ) assert base.cursor.fetchone() is None
def test_drop(self): current_cursor().execute("DROP MODEL IF EXISTS lsvr_model_test_drop") model_test = LinearSVR("lsvr_model_test_drop", ) model_test.fit("public.winequality", ["alcohol"], "quality") current_cursor().execute( "SELECT model_name FROM models WHERE model_name = 'lsvr_model_test_drop'" ) assert current_cursor().fetchone()[0] == "lsvr_model_test_drop" model_test.drop() current_cursor().execute( "SELECT model_name FROM models WHERE model_name = 'lsvr_model_test_drop'" ) assert current_cursor().fetchone() is None
def test_repr(self, model): assert "predictor |coefficient" in model.__repr__() model_repr = LinearSVR("model_repr") model_repr.drop() assert model_repr.__repr__() == "<LinearSVR>"
def load_model(name: str, cursor=None, input_relation: str = "", test_relation: str = ""): """ --------------------------------------------------------------------------- Loads a Vertica model and returns the associated object. Parameters ---------- name: str Model Name. cursor: DBcursor, optional Vertica database cursor. input_relation: str, optional Some automated functions may depend on the input relation. If the load_model function cannot find the input relation from the call string, you should fill it manually. test_relation: str, optional Relation to use to do the testing. All the methods will use this relation for the scoring. If empty, the training relation will be used as testing. Returns ------- model The model. """ check_types([("name", name, [str],), ("test_relation", test_relation, [str],), ("input_relation", input_relation, [str],),]) cursor = check_cursor(cursor)[0] does_exist = does_model_exist(name=name, cursor=cursor, raise_error=False) schema, name = schema_relation(name) schema, name = schema[1:-1], name[1:-1] assert does_exist, NameError("The model '{}' doesn't exist.".format(name)) if does_exist == 2: cursor.execute( "SELECT attr_name, value FROM verticapy.attr WHERE LOWER(model_name) = LOWER('{}')".format( str_column(name.lower()) ) ) result = cursor.fetchall() model_save = {} for elem in result: ldic = {} try: exec("result_tmp = {}".format(elem[1]), globals(), ldic) except: exec( "result_tmp = '{}'".format(elem[1].replace("'", "''")), globals(), ldic, ) result_tmp = ldic["result_tmp"] try: result_tmp = float(result_tmp) except: pass if result_tmp == None: result_tmp = "None" model_save[elem[0]] = result_tmp if model_save["type"] == "NearestCentroid": from verticapy.learn.neighbors import NearestCentroid model = NearestCentroid(name, cursor, model_save["p"]) model.centroids_ = tablesample(model_save["centroids"]) model.classes_ = model_save["classes"] elif model_save["type"] == "KNeighborsClassifier": from verticapy.learn.neighbors import KNeighborsClassifier model = KNeighborsClassifier( name, cursor, model_save["n_neighbors"], model_save["p"] ) model.classes_ = model_save["classes"] elif model_save["type"] == "KNeighborsRegressor": from verticapy.learn.neighbors import KNeighborsRegressor model = KNeighborsRegressor( name, cursor, model_save["n_neighbors"], model_save["p"] ) elif model_save["type"] == "KernelDensity": from verticapy.learn.neighbors import KernelDensity model = KernelDensity( name, cursor, model_save["bandwidth"], model_save["kernel"], model_save["p"], model_save["max_leaf_nodes"], model_save["max_depth"], model_save["min_samples_leaf"], model_save["nbins"], model_save["xlim"], ) model.y = "KDE" model.map = model_save["map"] model.tree_name = model_save["tree_name"] elif model_save["type"] == "LocalOutlierFactor": from verticapy.learn.neighbors import LocalOutlierFactor model = LocalOutlierFactor( name, cursor, model_save["n_neighbors"], model_save["p"] ) model.n_errors_ = model_save["n_errors"] elif model_save["type"] == "DBSCAN": from verticapy.learn.cluster import DBSCAN model = DBSCAN( name, cursor, model_save["eps"], model_save["min_samples"], model_save["p"], ) model.n_cluster_ = model_save["n_cluster"] model.n_noise_ = model_save["n_noise"] elif model_save["type"] == "CountVectorizer": from verticapy.learn.preprocessing import CountVectorizer model = CountVectorizer( name, cursor, model_save["lowercase"], model_save["max_df"], model_save["min_df"], model_save["max_features"], model_save["ignore_special"], model_save["max_text_size"], ) model.vocabulary_ = model_save["vocabulary"] model.stop_words_ = model_save["stop_words"] elif model_save["type"] == "SARIMAX": from verticapy.learn.tsa import SARIMAX model = SARIMAX( name, cursor, model_save["p"], model_save["d"], model_save["q"], model_save["P"], model_save["D"], model_save["Q"], model_save["s"], model_save["tol"], model_save["max_iter"], model_save["solver"], model_save["max_pik"], model_save["papprox_ma"], ) model.transform_relation = model_save["transform_relation"] model.coef_ = tablesample(model_save["coef"]) model.ma_avg_ = model_save["ma_avg"] if isinstance(model_save["ma_piq"], dict): model.ma_piq_ = tablesample(model_save["ma_piq"]) else: model.ma_piq_ = None model.ts = model_save["ts"] model.exogenous = model_save["exogenous"] model.deploy_predict_ = model_save["deploy_predict"] elif model_save["type"] == "VAR": from verticapy.learn.tsa import VAR model = VAR( name, cursor, model_save["p"], model_save["tol"], model_save["max_iter"], model_save["solver"], ) model.transform_relation = model_save["transform_relation"] model.coef_ = [] for i in range(len(model_save["X"])): model.coef_ += [tablesample(model_save["coef_{}".format(i)])] model.ts = model_save["ts"] model.deploy_predict_ = model_save["deploy_predict"] model.X = model_save["X"] if not(input_relation): model.input_relation = model_save["input_relation"] else: model.input_relation = input_relation model.X = model_save["X"] if model_save["type"] in ( "KNeighborsRegressor", "KNeighborsClassifier", "NearestCentroid", "SARIMAX", ): model.y = model_save["y"] model.test_relation = model_save["test_relation"] elif model_save["type"] not in ("CountVectorizer", "VAR"): model.key_columns = model_save["key_columns"] else: model_type = does_model_exist(name="{}.{}".format(schema, name), cursor=cursor, raise_error=False, return_model_type=True,) if model_type.lower() == "kmeans": cursor.execute( "SELECT GET_MODEL_SUMMARY (USING PARAMETERS model_name = '" + name + "')" ) info = cursor.fetchone()[0].replace("\n", " ") info = "kmeans(" + info.split("kmeans(")[1] elif model_type.lower() == "normalize_fit": from verticapy.learn.preprocessing import Normalizer model = Normalizer(name, cursor) model.param_ = model.get_attr("details") model.X = [ '"' + item + '"' for item in model.param_.values["column_name"] ] if "avg" in model.param_.values: model.parameters["method"] = "zscore" elif "max" in model.param_.values: model.parameters["method"] = "minmax" else: model.parameters["method"] = "robust_zscore" return model else: cursor.execute( "SELECT GET_MODEL_ATTRIBUTE (USING PARAMETERS model_name = '" + name + "', attr_name = 'call_string')" ) info = cursor.fetchone()[0].replace("\n", " ") if "SELECT " in info: info = info.split("SELECT ")[1].split("(") else: info = info.split("(") model_type = info[0].lower() info = info[1].split(")")[0].replace(" ", "").split("USINGPARAMETERS") if model_type == "svm_classifier" and "class_weights='none'" not in " ".join(info).lower(): parameters = "".join(info[1].split("class_weights=")[1].split("'")) parameters = parameters[3 : len(parameters)].split(",") del parameters[0] parameters += [ "class_weights=" + info[1].split("class_weights=")[1].split("'")[1] ] elif model_type != "svd": parameters = info[1].split(",") else: parameters = [] parameters = [item.split("=") for item in parameters] parameters_dict = {} for item in parameters: if len(item) > 1: parameters_dict[item[0]] = item[1] info = info[0] for elem in parameters_dict: if isinstance(parameters_dict[elem], str): parameters_dict[elem] = parameters_dict[elem].replace("'", "") if model_type == "rf_regressor": from verticapy.learn.ensemble import RandomForestRegressor model = RandomForestRegressor( name, cursor, int(parameters_dict["ntree"]), int(parameters_dict["mtry"]), int(parameters_dict["max_breadth"]), float(parameters_dict["sampling_size"]), int(parameters_dict["max_depth"]), int(parameters_dict["min_leaf_size"]), float(parameters_dict["min_info_gain"]), int(parameters_dict["nbins"]), ) elif model_type == "rf_classifier": from verticapy.learn.ensemble import RandomForestClassifier model = RandomForestClassifier( name, cursor, int(parameters_dict["ntree"]), int(parameters_dict["mtry"]), int(parameters_dict["max_breadth"]), float(parameters_dict["sampling_size"]), int(parameters_dict["max_depth"]), int(parameters_dict["min_leaf_size"]), float(parameters_dict["min_info_gain"]), int(parameters_dict["nbins"]), ) elif model_type == "xgb_classifier": from verticapy.learn.ensemble import XGBoostClassifier model = XGBoostClassifier( name, cursor, int(parameters_dict["max_ntree"]), int(parameters_dict["max_depth"]), int(parameters_dict["nbins"]), parameters_dict["objective"], parameters_dict["split_proposal_method"], float(parameters_dict["epsilon"]), float(parameters_dict["learning_rate"]), float(parameters_dict["min_split_loss"]), float(parameters_dict["weight_reg"]), float(parameters_dict["sampling_size"]), ) elif model_type == "xgb_regressor": from verticapy.learn.ensemble import XGBoostRegressor model = XGBoostRegressor( name, cursor, int(parameters_dict["max_ntree"]), int(parameters_dict["max_depth"]), int(parameters_dict["nbins"]), parameters_dict["objective"], parameters_dict["split_proposal_method"], float(parameters_dict["epsilon"]), float(parameters_dict["learning_rate"]), float(parameters_dict["min_split_loss"]), float(parameters_dict["weight_reg"]), float(parameters_dict["sampling_size"]), ) elif model_type == "logistic_reg": from verticapy.learn.linear_model import LogisticRegression model = LogisticRegression( name, cursor, parameters_dict["regularization"], float(parameters_dict["epsilon"]), float(parameters_dict["lambda"]), int(parameters_dict["max_iterations"]), parameters_dict["optimizer"], float(parameters_dict["alpha"]), ) elif model_type == "linear_reg": from verticapy.learn.linear_model import ( LinearRegression, Lasso, Ridge, ElasticNet, ) if parameters_dict["regularization"] == "none": model = LinearRegression( name, cursor, float(parameters_dict["epsilon"]), int(parameters_dict["max_iterations"]), parameters_dict["optimizer"], ) elif parameters_dict["regularization"] == "l1": model = Lasso( name, cursor, float(parameters_dict["epsilon"]), float(parameters_dict["lambda"]), int(parameters_dict["max_iterations"]), parameters_dict["optimizer"], ) elif parameters_dict["regularization"] == "l2": model = Ridge( name, cursor, float(parameters_dict["epsilon"]), float(parameters_dict["lambda"]), int(parameters_dict["max_iterations"]), parameters_dict["optimizer"], ) else: model = ElasticNet( name, cursor, float(parameters_dict["epsilon"]), float(parameters_dict["lambda"]), int(parameters_dict["max_iterations"]), parameters_dict["optimizer"], float(parameters_dict["alpha"]), ) elif model_type == "naive_bayes": from verticapy.learn.naive_bayes import NaiveBayes model = NaiveBayes(name, cursor, float(parameters_dict["alpha"])) elif model_type == "svm_regressor": from verticapy.learn.svm import LinearSVR model = LinearSVR( name, cursor, float(parameters_dict["epsilon"]), float(parameters_dict["C"]), True, float(parameters_dict["intercept_scaling"]), parameters_dict["intercept_mode"], float(parameters_dict["error_tolerance"]), int(parameters_dict["max_iterations"]), ) elif model_type == "svm_classifier": from verticapy.learn.svm import LinearSVC class_weights = parameters_dict["class_weights"].split(",") for idx, elem in enumerate(class_weights): try: class_weights[idx] = float(class_weights[idx]) except: class_weights[idx] = None model = LinearSVC( name, cursor, float(parameters_dict["epsilon"]), float(parameters_dict["C"]), True, float(parameters_dict["intercept_scaling"]), parameters_dict["intercept_mode"], class_weights, int(parameters_dict["max_iterations"]), ) elif model_type == "kmeans": from verticapy.learn.cluster import KMeans model = KMeans( name, cursor, int(info.split(",")[-1]), parameters_dict["init_method"], int(parameters_dict["max_iterations"]), float(parameters_dict["epsilon"]), ) model.cluster_centers_ = model.get_attr("centers") result = model.get_attr("metrics").values["metrics"][0] values = { "index": [ "Between-Cluster Sum of Squares", "Total Sum of Squares", "Total Within-Cluster Sum of Squares", "Between-Cluster SS / Total SS", "converged", ] } values["value"] = [ float(result.split("Between-Cluster Sum of Squares: ")[1].split("\n")[0]), float(result.split("Total Sum of Squares: ")[1].split("\n")[0]), float( result.split("Total Within-Cluster Sum of Squares: ")[1].split("\n")[0] ), float(result.split("Between-Cluster Sum of Squares: ")[1].split("\n")[0]) / float(result.split("Total Sum of Squares: ")[1].split("\n")[0]), result.split("Converged: ")[1].split("\n")[0] == "True", ] model.metrics_ = tablesample(values) elif model_type == "bisecting_kmeans": from verticapy.learn.cluster import BisectingKMeans model = BisectingKMeans( name, cursor, int(info.split(",")[-1]), int(parameters_dict["bisection_iterations"]), parameters_dict["split_method"], int(parameters_dict["min_divisible_cluster_size"]), parameters_dict["distance_method"], parameters_dict["kmeans_center_init_method"], int(parameters_dict["kmeans_max_iterations"]), float(parameters_dict["kmeans_epsilon"]), ) model.metrics_ = model.get_attr("Metrics") model.cluster_centers_ = model.get_attr("BKTree") elif model_type == "pca": from verticapy.learn.decomposition import PCA model = PCA(name, cursor, 0, bool(parameters_dict["scale"])) model.components_ = model.get_attr("principal_components") model.explained_variance_ = model.get_attr("singular_values") model.mean_ = model.get_attr("columns") elif model_type == "svd": from verticapy.learn.decomposition import SVD model = SVD(name, cursor) model.singular_values_ = model.get_attr("right_singular_vectors") model.explained_variance_ = model.get_attr("singular_values") elif model_type == "one_hot_encoder_fit": from verticapy.learn.preprocessing import OneHotEncoder model = OneHotEncoder(name, cursor) try: model.param_ = to_tablesample( query="SELECT category_name, category_level::varchar, category_level_index FROM (SELECT GET_MODEL_ATTRIBUTE(USING PARAMETERS model_name = '{}', attr_name = 'integer_categories')) VERTICAPY_SUBTABLE UNION ALL SELECT GET_MODEL_ATTRIBUTE(USING PARAMETERS model_name = '{}', attr_name = 'varchar_categories')".format( model.name, model.name ), cursor=model.cursor, ) except: try: model.param_ = model.get_attr("integer_categories") except: model.param_ = model.get_attr("varchar_categories") if not(input_relation): model.input_relation = info.split(",")[1].replace("'", "").replace("\\", "") else: model.input_relation = input_relation model.test_relation = test_relation if (test_relation) else model.input_relation if model_type not in ("kmeans", "pca", "svd", "one_hot_encoder_fit"): model.X = info.split(",")[3 : len(info.split(","))] model.X = [item.replace("'", "").replace("\\", "") for item in model.X] model.y = info.split(",")[2].replace("'", "").replace("\\", "") elif model_type in ( "svd", "pca", "one_hot_encoder_fit", "normalizer", "kmeans", "bisectingkmeans", ): model.X = info.split(",")[2 : len(info.split(","))] model.X = [item.replace("'", "").replace("\\", "") for item in model.X] if model_type in ("naive_bayes", "rf_classifier", "xgb_classifier"): try: cursor.execute( "SELECT DISTINCT {} FROM {} WHERE {} IS NOT NULL ORDER BY 1".format( model.y, model.input_relation, model.y ) ) classes = cursor.fetchall() model.classes_ = [item[0] for item in classes] except: model.classes_ = [0, 1] elif model_type in ("svm_classifier", "logistic_reg"): model.classes_ = [0, 1] if model_type in ("svm_classifier", "svm_regressor", "logistic_reg", "linear_reg",): model.coef_ = model.get_attr("details") return model