def train_test(self, train_path, test_path=None): # load train and (maybe) test data metadata = MetaData(class_column=self.class_column, train_path=train_path, test_path=test_path) self.num_classes = metadata.k_classes self.num_features = metadata.d_features # if necessary, cast judgment metric into its binary/multiary equivalent if self.num_classes == 2: if self.judgment_metric in [Metrics.F1_MICRO, Metrics.F1_MACRO]: self.judgment_metric = Metrics.F1 elif self.judgment_metric in [ Metrics.ROC_AUC_MICRO, Metrics.ROC_AUC_MACRO ]: self.judgment_metric = Metrics.ROC_AUC else: if self.judgment_metric == Metrics.F1: self.judgment_metric = Metrics.F1_MACRO elif self.judgment_metric == Metrics.ROC_AUC: self.judgment_metric = Metrics.ROC_AUC_MACRO # load training data train_data = self.load_data(train_path) # if necessary, generate permanent train/test split if test_path is not None: test_data = self.load_data(test_path) all_data = pd.concat([train_data, test_data]) else: all_data = train_data train_data, test_data = train_test_split( train_data, test_size=self.testing_ratio, random_state=self.random_state) # extract feature matrix and labels from raw data self.encoder = DataEncoder(class_column=self.class_column) self.encoder.fit(all_data) X_train, y_train = self.encoder.transform(train_data) X_test, y_test = self.encoder.transform(test_data) # create and cross-validate pipeline self.make_pipeline() cv_scores = self.cross_validate(X_train, y_train) # train and test the final model self.pipeline.fit(X_train, y_train) test_scores = self.test_final_model(X_test, y_test) return {'cv': cv_scores, 'test': test_scores}
def train_test(self, dataset): """Train and test this model using Cross Validation and Holdout. Args: dataset (Dataset): Dataset object from database. Returns: dict: Dictionary containing: * cv (list): The cross validation scores array * test (dict): The test scores dictionary """ self.num_classes = dataset.k_classes self.num_features = dataset.d_features # if necessary, cast judgment metric into its binary/multiary equivalent if self.num_classes == 2: if self.judgment_metric in [Metrics.F1_MICRO, Metrics.F1_MACRO]: self.judgment_metric = Metrics.F1 elif self.judgment_metric in [ Metrics.ROC_AUC_MICRO, Metrics.ROC_AUC_MACRO ]: self.judgment_metric = Metrics.ROC_AUC else: if self.judgment_metric == Metrics.F1: self.judgment_metric = Metrics.F1_MACRO elif self.judgment_metric == Metrics.ROC_AUC: self.judgment_metric = Metrics.ROC_AUC_MACRO # load training data train_data, test_data = dataset.load(self.testing_ratio, self.random_state) # extract feature matrix and labels from raw data self.encoder = DataEncoder(class_column=self.class_column) self.encoder.fit(train_data) X_train, y_train = self.encoder.transform(train_data) X_test, y_test = self.encoder.transform(test_data) # create and cross-validate pipeline self._make_pipeline() cv_scores = self._cross_validate(X_train, y_train) # train and test the final model self.pipeline.fit(X_train, y_train) test_scores = self._test_final_model(X_test, y_test) return {'cv': cv_scores, 'test': test_scores}
def train_test(self, dataset): self.num_classes = dataset.k_classes self.num_features = dataset.d_features # if necessary, cast judgment metric into its binary/multiary equivalent if self.num_classes == 2: if self.judgment_metric in [Metrics.F1_MICRO, Metrics.F1_MACRO]: self.judgment_metric = Metrics.F1 elif self.judgment_metric in [ Metrics.ROC_AUC_MICRO, Metrics.ROC_AUC_MACRO ]: self.judgment_metric = Metrics.ROC_AUC else: if self.judgment_metric == Metrics.F1: self.judgment_metric = Metrics.F1_MACRO elif self.judgment_metric == Metrics.ROC_AUC: self.judgment_metric = Metrics.ROC_AUC_MACRO # load training data train_data, test_data = dataset.load(self.testing_ratio, self.random_state) # extract feature matrix and labels from raw data self.encoder = DataEncoder(class_column=self.class_column) self.encoder.fit(train_data) X_train, y_train = self.encoder.transform(train_data) X_test, y_test = self.encoder.transform(test_data) # create and cross-validate pipeline self.make_pipeline() cv_scores = self.cross_validate(X_train, y_train) # train and test the final model self.pipeline.fit(X_train, y_train) test_scores = self.test_final_model(X_test, y_test) return {'cv': cv_scores, 'test': test_scores}
class Model(object): """ This class contains everything needed to run an end-to-end ATM classifier pipeline. It is initialized with a set of parameters and trained like a normal sklearn model. This class can be pickled and saved to disk, then unpickled outside of ATM and used to classify new datasets. """ # these are special keys that are used for general purpose # things like scaling, normalization, PCA, etc SCALE = "_scale" WHITEN = "_whiten" MINMAX = "_scale_minmax" PCA = "_pca" PCA_DIMS = "_pca_dimensions" # list of all such keys ATM_KEYS = [SCALE, WHITEN, MINMAX, PCA, PCA_DIMS] # number of folds for cross-validation (arbitrary, for speed) N_FOLDS = 5 def __init__(self, code, params, judgment_metric, label_column, testing_ratio=0.3): """ Parameters: code: the short method code (as defined in constants.py) judgment_metric: string that indicates which metric should be optimized for. params: parameters passed to the sklearn classifier constructor class_: sklearn classifier class """ # configuration & database self.code = code self.params = params self.judgment_metric = judgment_metric self.label_column = label_column self.testing_ratio = testing_ratio # load the classifier method's class path = Method(METHODS_MAP[code]).class_path.split('.') mod_str, cls_str = '.'.join(path[:-1]), path[-1] mod = import_module(mod_str) self.class_ = getattr(mod, cls_str) # pipelining self.pipeline = None # persistent random state self.random_state = np.random.randint(1e7) def load_data(self, path, dropvals=None, sep=','): # load data as a Pandas dataframe data = pd.read_csv(path, skipinitialspace=True, na_values=dropvals, sep=sep) # drop rows with any NA values return data.dropna(how='any') def make_pipeline(self): """ Makes the classifier as well as scaling or dimension reduction steps. """ # create a list of steps, starting with the data encoder steps = [] # create a classifier with specified parameters hyperparameters = { k: v for k, v in self.params.iteritems() if k not in Model.ATM_KEYS } atm_params = { k: v for k, v in self.params.iteritems() if k in Model.ATM_KEYS } # do special conversions hyperparameters = self.special_conversions(hyperparameters) self.trainable_params = hyperparameters classifier = self.class_(**hyperparameters) self.dimensions = self.num_features if Model.PCA in atm_params and atm_params[Model.PCA]: whiten = (Model.WHITEN in atm_params and atm_params[Model.WHITEN]) pca_dims = atm_params[Model.PCA_DIMS] # PCA dimension in atm_params is a float reprsenting percentages of # features to use if pca_dims >= 1: self.dimensions = int(pca_dims) else: self.dimensions = int(pca_dims * float(self.num_features)) print "*** Using PCA to reduce %d features to %d dimensions" %\ (self.num_features, self.dimensions) pca = decomposition.PCA(n_components=self.dimensions, whiten=whiten) steps.append(('pca', pca)) # should we scale the data? if atm_params.get(Model.SCALE): steps.append(('standard_scale', StandardScaler())) elif self.params.get(Model.MINMAX): steps.append(('minmax_scale', MinMaxScaler())) # add the classifier as the final step in the pipeline steps.append((self.code, classifier)) self.pipeline = Pipeline(steps) def cross_validate(self, X, y): binary = self.num_classes == 2 df, cv_scores = cross_validate_pipeline(pipeline=self.pipeline, X=X, y=y, binary=binary, n_folds=self.N_FOLDS) self.cv_judgment_metric = np.mean(df[self.judgment_metric]) self.cv_judgment_metric_stdev = np.std(df[self.judgment_metric]) return cv_scores def test_final_model(self, X, y): """ Test the (already trained) model pipeline on the provided test data (X and y). Store the test judgment metric and return the rest of the metrics as a hierarchical dictionary. """ # time the prediction starttime = time.time() y_preds = self.pipeline.predict(X) binary = self.num_classes == 2 test_scores = test_pipeline(self.pipeline, X, y, binary) total = time.time() - starttime self.avg_prediction_time = total / float(len(y)) self.test_judgment_metric = test_scores.get(self.judgment_metric) return test_scores def train_test(self, train_path, test_path=None): # load train and (maybe) test data metadata = MetaData(label_column=self.label_column, train_path=train_path, test_path=test_path) self.num_classes = metadata.k_classes self.num_features = metadata.d_features # if necessary, cast judgment metric into its binary/multiary equivalent if self.num_classes == 2: if self.judgment_metric in [Metrics.F1_MICRO, Metrics.F1_MACRO]: self.judgment_metric = Metrics.F1 elif self.judgment_metric in [ Metrics.ROC_AUC_MICRO, Metrics.ROC_AUC_MACRO ]: self.judgment_metric = Metrics.ROC_AUC else: if self.judgment_metric == Metrics.F1: self.judgment_metric = Metrics.F1_MACRO elif self.judgment_metric == Metrics.ROC_AUC: self.judgment_metric = Metrics.ROC_AUC_MACRO # load training data train_data = self.load_data(train_path) # if necessary, generate permanent train/test split if test_path is not None: test_data = self.load_data(test_path) else: train_data, test_data = train_test_split( train_data, test_size=self.testing_ratio, random_state=self.random_state) # extract feature matrix and labels from raw data self.encoder = DataEncoder(label_column=self.label_column) X_train, y_train = self.encoder.fit_transform(train_data) X_test, y_test = self.encoder.transform(test_data) # create and cross-validate pipeline self.make_pipeline() cv_scores = self.cross_validate(X_train, y_train) # train and test the final model self.pipeline.fit(X_train, y_train) test_scores = self.test_final_model(X_test, y_test) return {'cv': cv_scores, 'test': test_scores} def predict(self, data): """ Use the trained encoder and pipeline to transform training data into predicted labels """ X, _ = self.encoder.transform(data) return self.pipeline.predict(X) def special_conversions(self, params): """ TODO: Make this logic into subclasses ORRRR, should make each enumerator handle it in a static function something like: @staticmethod def transform_params(params_dict): # does classifier-specific changes return params_dict """ ### GPC ### if self.code == "gp": if params["kernel"] == "constant": params["kernel"] = ConstantKernel() elif params["kernel"] == "rbf": params["kernel"] = RBF() elif params["kernel"] == "matern": params["kernel"] = Matern(nu=params["nu"]) del params["nu"] elif params["kernel"] == "rational_quadratic": params["kernel"] = RationalQuadratic( length_scale=params["length_scale"], alpha=params["alpha"]) del params["length_scale"] del params["alpha"] elif params["kernel"] == "exp_sine_squared": params["kernel"] = ExpSineSquared( length_scale=params["length_scale"], periodicity=params["periodicity"]) del params["length_scale"] del params["periodicity"] ### MLP ### if self.code == "mlp": params["hidden_layer_sizes"] = [] # set layer topology if int(params["num_hidden_layers"]) == 1: params["hidden_layer_sizes"].append( params["hidden_size_layer1"]) del params["hidden_size_layer1"] elif int(params["num_hidden_layers"]) == 2: params["hidden_layer_sizes"].append( params["hidden_size_layer1"]) params["hidden_layer_sizes"].append( params["hidden_size_layer2"]) del params["hidden_size_layer1"] del params["hidden_size_layer2"] elif int(params["num_hidden_layers"]) == 3: params["hidden_layer_sizes"].append( params["hidden_size_layer1"]) params["hidden_layer_sizes"].append( params["hidden_size_layer2"]) params["hidden_layer_sizes"].append( params["hidden_size_layer3"]) del params["hidden_size_layer1"] del params["hidden_size_layer2"] del params["hidden_size_layer3"] params["hidden_layer_sizes"] = [ int(x) for x in params["hidden_layer_sizes"] ] # convert to ints # delete our fabricated keys del params["num_hidden_layers"] # print "Added stuff for DBNs! %s" % params ### DBN ### if self.code == "dbn": # print "Adding stuff for DBNs! %s" % params params["layer_sizes"] = [params["inlayer_size"]] # set layer topology if int(params["num_hidden_layers"]) == 1: params["layer_sizes"].append(params["hidden_size_layer1"]) del params["hidden_size_layer1"] elif int(params["num_hidden_layers"]) == 2: params["layer_sizes"].append(params["hidden_size_layer1"]) params["layer_sizes"].append(params["hidden_size_layer2"]) del params["hidden_size_layer1"] del params["hidden_size_layer2"] elif int(params["num_hidden_layers"]) == 3: params["layer_sizes"].append(params["hidden_size_layer1"]) params["layer_sizes"].append(params["hidden_size_layer2"]) params["layer_sizes"].append(params["hidden_size_layer3"]) del params["hidden_size_layer1"] del params["hidden_size_layer2"] del params["hidden_size_layer3"] params["layer_sizes"].append(params["outlayer_size"]) params["layer_sizes"] = [int(x) for x in params["layer_sizes"] ] # convert to ints # set activation function if params["output_act_funct"] == "Linear": params["output_act_funct"] = Linear() elif params["output_act_funct"] == "Sigmoid": params["output_act_funct"] = Sigmoid() elif params["output_act_funct"] == "Softmax": params["output_act_funct"] = Softmax() elif params["output_act_funct"] == "tanh": params["output_act_funct"] = Tanh() params["epochs"] = int(params["epochs"]) # delete our fabricated keys del params["num_hidden_layers"] del params["inlayer_size"] del params["outlayer_size"] # return the updated parameter vector return params
class Model(object): """ This class contains everything needed to run an end-to-end ATM classifier pipeline. It is initialized with a set of parameters and trained like a normal sklearn model. This class can be pickled and saved to disk, then unpickled outside of ATM and used to classify new datasets. """ # these are special keys that are used for general purpose # things like scaling, normalization, PCA, etc SCALE = "_scale" WHITEN = "_whiten" MINMAX = "_scale_minmax" PCA = "_pca" PCA_DIMS = "_pca_dimensions" # list of all such keys ATM_KEYS = [SCALE, WHITEN, MINMAX, PCA, PCA_DIMS] # number of folds for cross-validation (arbitrary, for speed) N_FOLDS = 5 def __init__(self, method, params, judgment_metric, class_column, testing_ratio=0.3, verbose_metrics=False): """ Parameters: method: the short method code (as defined in constants.py) or path to method json judgment_metric: string that indicates which metric should be optimized for. params: parameters passed to the sklearn classifier constructor class_: sklearn classifier class """ # configuration & database self.method = method self.params = params self.judgment_metric = judgment_metric self.class_column = class_column self.testing_ratio = testing_ratio self.verbose_metrics = verbose_metrics # load the classifier method's class path = Method(method).class_path.split('.') mod_str, cls_str = '.'.join(path[:-1]), path[-1] mod = import_module(mod_str) self.class_ = getattr(mod, cls_str) # pipelining self.pipeline = None # persistent random state self.random_state = np.random.randint(1e7) def load_data(self, path, dropvals=None, sep=','): # load data as a Pandas dataframe data = pd.read_csv(path, skipinitialspace=True, na_values=dropvals, sep=sep) # drop rows with any NA values return data.dropna(how='any') def make_pipeline(self): """ Makes the classifier as well as scaling or dimension reduction steps. """ # create a list of steps, starting with the data encoder steps = [] # create a classifier with specified parameters hyperparameters = { k: v for k, v in list(self.params.items()) if k not in Model.ATM_KEYS } atm_params = { k: v for k, v in list(self.params.items()) if k in Model.ATM_KEYS } # do special conversions hyperparameters = self.special_conversions(hyperparameters) classifier = self.class_(**hyperparameters) if Model.PCA in atm_params and atm_params[Model.PCA]: whiten = (Model.WHITEN in atm_params and atm_params[Model.WHITEN]) pca_dims = atm_params[Model.PCA_DIMS] # PCA dimension in atm_params is a float reprsenting percentages of # features to use if pca_dims < 1: dimensions = int(pca_dims * float(self.num_features)) logger.info( "Using PCA to reduce %d features to %d dimensions" % (self.num_features, dimensions)) pca = decomposition.PCA(n_components=dimensions, whiten=whiten) steps.append(('pca', pca)) # should we scale the data? if atm_params.get(Model.SCALE): steps.append(('standard_scale', StandardScaler())) elif self.params.get(Model.MINMAX): steps.append(('minmax_scale', MinMaxScaler())) # add the classifier as the final step in the pipeline steps.append((self.method, classifier)) self.pipeline = Pipeline(steps) def cross_validate(self, X, y): # TODO: this is hacky. See https://github.com/HDI-Project/ATM/issues/48 binary = self.num_classes == 2 kwargs = {} if self.verbose_metrics: kwargs['include_curves'] = True if not binary: kwargs['include_per_class'] = True df, cv_scores = cross_validate_pipeline(pipeline=self.pipeline, X=X, y=y, binary=binary, n_folds=self.N_FOLDS, **kwargs) self.cv_judgment_metric = np.mean(df[self.judgment_metric]) self.cv_judgment_metric_stdev = np.std(df[self.judgment_metric]) cv_stdev = (2 * self.cv_judgment_metric_stdev) self.mu_sigma_judgment_metric = self.cv_judgment_metric - cv_stdev return cv_scores def test_final_model(self, X, y): """ Test the (already trained) model pipeline on the provided test data (X and y). Store the test judgment metric and return the rest of the metrics as a hierarchical dictionary. """ # time the prediction start_time = time.time() total = time.time() - start_time self.avg_predict_time = old_div(total, float(len(y))) # TODO: this is hacky. See https://github.com/HDI-Project/ATM/issues/48 binary = self.num_classes == 2 kwargs = {} if self.verbose_metrics: kwargs['include_curves'] = True if not binary: kwargs['include_per_class'] = True # compute the actual test scores! test_scores = test_pipeline(self.pipeline, X, y, binary, **kwargs) # save meta-metrics self.test_judgment_metric = test_scores.get(self.judgment_metric) return test_scores def train_test(self, train_path, test_path=None): # load train and (maybe) test data metadata = MetaData(class_column=self.class_column, train_path=train_path, test_path=test_path) self.num_classes = metadata.k_classes self.num_features = metadata.d_features # if necessary, cast judgment metric into its binary/multiary equivalent if self.num_classes == 2: if self.judgment_metric in [Metrics.F1_MICRO, Metrics.F1_MACRO]: self.judgment_metric = Metrics.F1 elif self.judgment_metric in [ Metrics.ROC_AUC_MICRO, Metrics.ROC_AUC_MACRO ]: self.judgment_metric = Metrics.ROC_AUC else: if self.judgment_metric == Metrics.F1: self.judgment_metric = Metrics.F1_MACRO elif self.judgment_metric == Metrics.ROC_AUC: self.judgment_metric = Metrics.ROC_AUC_MACRO # load training data train_data = self.load_data(train_path) # if necessary, generate permanent train/test split if test_path is not None: test_data = self.load_data(test_path) all_data = pd.concat([train_data, test_data]) else: all_data = train_data train_data, test_data = train_test_split( train_data, test_size=self.testing_ratio, random_state=self.random_state) # extract feature matrix and labels from raw data self.encoder = DataEncoder(class_column=self.class_column) self.encoder.fit(all_data) X_train, y_train = self.encoder.transform(train_data) X_test, y_test = self.encoder.transform(test_data) # create and cross-validate pipeline self.make_pipeline() cv_scores = self.cross_validate(X_train, y_train) # train and test the final model self.pipeline.fit(X_train, y_train) test_scores = self.test_final_model(X_test, y_test) return {'cv': cv_scores, 'test': test_scores} def predict(self, data): """ Use the trained encoder and pipeline to transform training data into predicted labels data: pd.DataFrame of data for which to predict classes returns: pd.Series populated with predictions, with index matching data. """ X, _ = self.encoder.transform(data) predictions = self.pipeline.predict(X) labels = self.encoder.label_encoder.inverse_transform(predictions) labels = pd.Series(labels, index=data.index) return labels def special_conversions(self, params): """ TODO: replace this logic with something better """ # create list parameters lists = defaultdict(list) element_regex = re.compile(r'(.*)\[(\d)\]') for name, param in list(params.items()): # look for variables of the form "param_name[1]" match = element_regex.match(name) if match: # name of the list parameter lname = match.groups()[0] # index of the list item index = int(match.groups()[1]) lists[lname].append((index, param)) # drop the element parameter from our list del params[name] for lname, items in list(lists.items()): # drop the list size parameter del params['len(%s)' % lname] # sort the list by index params[lname] = [val for idx, val in sorted(items)] # Gaussian process classifier if self.method == "gp": if params["kernel"] == "constant": params["kernel"] = ConstantKernel() elif params["kernel"] == "rbf": params["kernel"] = RBF() elif params["kernel"] == "matern": params["kernel"] = Matern(nu=params["nu"]) del params["nu"] elif params["kernel"] == "rational_quadratic": params["kernel"] = RationalQuadratic( length_scale=params["length_scale"], alpha=params["alpha"]) del params["length_scale"] del params["alpha"] elif params["kernel"] == "exp_sine_squared": params["kernel"] = ExpSineSquared( length_scale=params["length_scale"], periodicity=params["periodicity"]) del params["length_scale"] del params["periodicity"] # return the updated parameter vector return params