def fit(self, X_train, Y_train=None, I_train=None): """Fits data in the classifier. Args: X_train (np.array): Array of training features. Y_train (np.array): Array of training labels. I_train (np.array): Array of training indexes. """ logger.info('Clustering with classifier ...') start = time.time() # Creating a subgraph self.subgraph = KNNSubgraph(X_train, Y_train, I_train) # Performing the best minimum cut on the subgraph self._best_minimum_cut(self.min_k, self.max_k) # Clustering the data with best `k` value self._clustering(self.subgraph.best_k) # The subgraph has been properly trained self.subgraph.trained = True end = time.time() train_time = end - start logger.info('Classifier has been clustered with.') logger.info('Number of clusters: %d.', self.subgraph.n_clusters) logger.info('Clustering time: %s seconds.', train_time)
def fit(self, X_train, Y_train=None): """Fits data in the classifier. Args: X_train (np.array): Array of training features. Y_train (np.array): Array of training labels. """ logger.info('Clustering with classifier ...') # Initializing the timer start = time.time() # Creating a subgraph self.subgraph = KNNSubgraph(X_train, Y_train) # Checks if it is supposed to use pre-computed distances if self.pre_computed_distance: # Checks if its size is the same as the subgraph's amount of nodes if self.pre_distances.shape[ 0] != self.subgraph.n_nodes or self.pre_distances.shape[ 1] != self.subgraph.n_nodes: # If not, raises an error raise e.BuildError( 'Pre-computed distance matrix should have the size of `n_nodes x n_nodes`' ) # Performing the best minimum cut on the subgraph self._best_minimum_cut(self.min_k, self.max_k) # Clustering the data with best `k` value self._clustering(self.subgraph.best_k) # The subgraph has been properly trained self.subgraph.trained = True # Ending timer end = time.time() # Calculating training task time train_time = end - start logger.info('Classifier has been clustered with.') logger.info(f'Number of clusters: {self.subgraph.n_clusters}.') logger.info(f'Clustering time: {train_time} seconds.')
def predict(self, X_test, I_test=None): """Predicts new data using the pre-trained classifier. Args: X_test (np.array): Array of features. I_test (np.array): Array of indexes. Returns: A list of predictions for each record of the data. """ logger.info('Predicting data ...') start = time.time() # Creating a prediction subgraph pred_subgraph = KNNSubgraph(X_test, I=I_test) # Gathering the best `k` value best_k = self.subgraph.best_k # Creating an array of distances distances = np.zeros(best_k + 1) # Creating an array of nearest neighbours indexes neighbours_idx = np.zeros(best_k + 1) for i in range(pred_subgraph.n_nodes): # Defines the current cost cost = c.FLOAT_MAX * -1 # Filling array of distances with maximum value distances.fill(c.FLOAT_MAX) for j in range(self.subgraph.n_nodes): if j != i: if self.pre_computed_distance: distances[best_k] = self.pre_distances[ pred_subgraph.nodes[i].idx][ self.subgraph.nodes[j].idx] else: distances[best_k] = self.distance_fn( pred_subgraph.nodes[i].features, self.subgraph.nodes[j].features) # Apply node `j` as a neighbour neighbours_idx[best_k] = j # Gathers current `k` cur_k = best_k # While current `k` is bigger than 0 and the `k` distance is smaller than `k-1` distance while cur_k > 0 and distances[cur_k] < distances[cur_k - 1]: # Swaps the distance from `k` and `k-1` distances[cur_k], distances[cur_k - 1] = distances[ cur_k - 1], distances[cur_k] # Swaps the neighbours indexex from `k` and `k-1` neighbours_idx[cur_k], neighbours_idx[ cur_k - 1] = neighbours_idx[cur_k - 1], neighbours_idx[cur_k] # Decrements `k` cur_k -= 1 # Defining the density as 0 density = 0.0 for k in range(best_k): density += np.exp(-distances[k] / self.subgraph.constant) density /= best_k # Scale the density between minimum and maximum values density = ((c.MAX_DENSITY - 1) * (density - self.subgraph.min_density) / (self.subgraph.max_density - self.subgraph.min_density + c.EPSILON)) + 1 for k in range(best_k): if distances[k] != c.FLOAT_MAX: # Gathers the node's neighbour neighbour = int(neighbours_idx[k]) # Calculate the temporary cost temp_cost = np.minimum(self.subgraph.nodes[neighbour].cost, density) if temp_cost > cost: cost = temp_cost # Propagates the predicted label from the neighbour pred_subgraph.nodes[ i].predicted_label = self.subgraph.nodes[ neighbour].predicted_label # Creating the list of predictions preds = [pred.predicted_label for pred in pred_subgraph.nodes] end = time.time() predict_time = end - start logger.info('Data has been predicted.') logger.info('Prediction time: %s seconds.', predict_time) return preds
class KNNSupervisedOPF(OPF): """A KNNSupervisedOPF which implements the supervised version of OPF classifier with a KNN subgraph. References: J. P. Papa and A. X. Falcão. A Learning Algorithm for the Optimum-Path Forest Classifier. Graph-Based Representations in Pattern Recognition (2009). """ def __init__(self, max_k=1, distance='log_squared_euclidean', pre_computed_distance=None): """Initialization method. Args: max_k (int): Maximum `k` value for cutting the subgraph. distance (str): An indicator of the distance metric to be used. pre_computed_distance (str): A pre-computed distance file for feeding into OPF. """ logger.info('Overriding class: OPF -> KNNSupervisedOPF.') super(KNNSupervisedOPF, self).__init__(distance, pre_computed_distance) # Defining the maximum `k` value for cutting the subgraph self.max_k = max_k logger.info('Class overrided.') @property def max_k(self): """int: Maximum `k` value for cutting the subgraph. """ return self._max_k @max_k.setter def max_k(self, max_k): if not isinstance(max_k, int): raise e.TypeError('`max_k` should be an integer') if max_k < 1: raise e.ValueError('`max_k` should be >= 1') self._max_k = max_k def _clustering(self, force_prototype=False): """Clusters the subgraph. Args: force_prototype (bool): Whether clustering should for each class to have at least one prototype. """ for i in range(self.subgraph.n_nodes): # For every adjacent node of `i` for j in self.subgraph.nodes[i].adjacency: # Making sure that variable is an integer j = int(j) # Checks if node `i` density is equals as node `j` density if self.subgraph.nodes[i].density == self.subgraph.nodes[ j].density: # Marks the insertion flag as True insert = True # For every adjacent node of `j` for l in self.subgraph.nodes[j].adjacency: # Making sure that variable is an integer l = int(l) # Checks if it is the same node as `i` if i == l: insert = False if insert: self.subgraph.nodes[j].adjacency.insert(0, i) # Creating a maximum heap h = Heap(size=self.subgraph.n_nodes, policy='max') for i in range(self.subgraph.n_nodes): # Updates the node's cost on the heap h.cost[i] = self.subgraph.nodes[i].cost # Defines node's `i` predecessor as NIL self.subgraph.nodes[i].pred = c.NIL # And its root as its same identifier self.subgraph.nodes[i].root = i # Inserts the node in the heap h.insert(i) while not h.is_empty(): p = h.remove() # Appends its index to the ordered list self.subgraph.idx_nodes.append(p) if self.subgraph.nodes[p].pred == c.NIL: # Updates its cost on the heap h.cost[p] = self.subgraph.nodes[p].density # Defines its predicted label as the node's true label self.subgraph.nodes[p].predicted_label = self.subgraph.nodes[ p].label # Apply current node's cost as the heap's cost self.subgraph.nodes[p].cost = h.cost[p] # For every possible adjacent node for q in self.subgraph.nodes[p].adjacency: # Making sure that variable is an integer q = int(q) if h.color[q] != c.BLACK: current_cost = np.minimum(h.cost[p], self.subgraph.nodes[q].density) # If prototypes should be forced to belong to a class if force_prototype: if self.subgraph.nodes[p].label != self.subgraph.nodes[ q].label: current_cost = -c.FLOAT_MAX # If current cost is bigger than heap's cost if current_cost > h.cost[q]: # Apply `q` predecessor as `p` self.subgraph.nodes[q].pred = p # Gathers the same root's identifier self.subgraph.nodes[q].root = self.subgraph.nodes[ p].root # And its cluster label self.subgraph.nodes[ q].predicted_label = self.subgraph.nodes[ p].predicted_label # Updates node `q` on the heap with the current cost h.update(q, current_cost) def _learn(self, X_train, Y_train, I_train, X_val, Y_val, I_val): """Learns the best `k` value over the validation set. Args: X_train (np.array): Array of training features. Y_train (np.array): Array of training labels. I_train (np.array): Array of training indexes. X_val (np.array): Array of validation features. Y_val (np.array): Array of validation labels. I_val (np.array): Array of validation indexes. """ logger.info('Learning best `k` value ...') # Creating a subgraph self.subgraph = KNNSubgraph(X_train, Y_train, I_train) if self.pre_computed_distance: if self.pre_distances.shape[ 0] != self.subgraph.n_nodes or self.pre_distances.shape[ 1] != self.subgraph.n_nodes: raise e.BuildError( 'Pre-computed distance matrix should have the size of `n_nodes x n_nodes`' ) # Defining initial maximum accuracy as 0 max_acc = 0.0 for k in range(1, self.max_k + 1): # Gathers current `k` as subgraph's best `k` self.subgraph.best_k = k # Calculate the arcs using the current `k` value self.subgraph.create_arcs(k, self.distance_fn, self.pre_computed_distance, self.pre_distances) # Calculate the p.d.f. using the current `k` value self.subgraph.calculate_pdf(k, self.distance_fn, self.pre_computed_distance, self.pre_distances) # Clusters the subgraph self._clustering() # Calculate the predictions over the validation set preds = self.predict(X_val, I_val) # Calculating the accuracy acc = g.opf_accuracy(Y_val, preds) if acc > max_acc: max_acc = acc best_k = k logger.info('Accuracy over k = %d: %s', k, acc) self.subgraph.destroy_arcs() self.subgraph.best_k = best_k def fit(self, X_train, Y_train, X_val, Y_val, I_train=None, I_val=None): """Fits data in the classifier. Args: X_train (np.array): Array of training features. Y_train (np.array): Array of training labels. X_val (np.array): Array of validation features. Y_val (np.array): Array of validation labels. I_train (np.array): Array of training indexes. I_val (np.array): Array of validation indexes. """ logger.info('Fitting classifier ...') start = time.time() # Performing the learning process in order to find the best `k` value self._learn(X_train, Y_train, I_train, X_val, Y_val, I_val) # Creating arcs with the best `k` value self.subgraph.create_arcs(self.subgraph.best_k, self.distance_fn, self.pre_computed_distance, self.pre_distances) # Calculating p.d.f. with the best `k` value self.subgraph.calculate_pdf(self.subgraph.best_k, self.distance_fn, self.pre_computed_distance, self.pre_distances) # Clustering subgraph forcing each class to have at least one prototype self._clustering(force_prototype=True) self.subgraph.destroy_arcs() # The subgraph has been properly trained self.subgraph.trained = True end = time.time() train_time = end - start logger.info('Classifier has been fitted with k = %d.', self.subgraph.best_k) logger.info('Training time: %s seconds.', train_time) def predict(self, X_test, I_test=None): """Predicts new data using the pre-trained classifier. Args: X_test (np.array): Array of features. I_test (np.array): Array of indexes. Returns: A list of predictions for each record of the data. """ logger.info('Predicting data ...') start = time.time() # Creating a prediction subgraph pred_subgraph = KNNSubgraph(X_test, I=I_test) # Gathering the best `k` value best_k = self.subgraph.best_k # Creating an array of distances distances = np.zeros(best_k + 1) # Creating an array of nearest neighbours indexes neighbours_idx = np.zeros(best_k + 1) for i in range(pred_subgraph.n_nodes): # Defines the current cost cost = c.FLOAT_MAX * -1 # Filling array of distances with maximum value distances.fill(c.FLOAT_MAX) for j in range(self.subgraph.n_nodes): if j != i: if self.pre_computed_distance: distances[best_k] = self.pre_distances[ pred_subgraph.nodes[i].idx][ self.subgraph.nodes[j].idx] else: distances[best_k] = self.distance_fn( pred_subgraph.nodes[i].features, self.subgraph.nodes[j].features) # Apply node `j` as a neighbour neighbours_idx[best_k] = j # Gathers current `k` cur_k = best_k # While current `k` is bigger than 0 and the `k` distance is smaller than `k-1` distance while cur_k > 0 and distances[cur_k] < distances[cur_k - 1]: # Swaps the distance from `k` and `k-1` distances[cur_k], distances[cur_k - 1] = distances[ cur_k - 1], distances[cur_k] # Swaps the neighbours indexex from `k` and `k-1` neighbours_idx[cur_k], neighbours_idx[ cur_k - 1] = neighbours_idx[cur_k - 1], neighbours_idx[cur_k] # Decrements `k` cur_k -= 1 # Defining the density as 0 density = 0.0 for k in range(best_k): density += np.exp(-distances[k] / self.subgraph.constant) density /= best_k # Scale the density between minimum and maximum values density = ((c.MAX_DENSITY - 1) * (density - self.subgraph.min_density) / (self.subgraph.max_density - self.subgraph.min_density + c.EPSILON)) + 1 for k in range(best_k): if distances[k] != c.FLOAT_MAX: # Gathers the node's neighbour neighbour = int(neighbours_idx[k]) # Calculate the temporary cost temp_cost = np.minimum(self.subgraph.nodes[neighbour].cost, density) if temp_cost > cost: cost = temp_cost # Propagates the predicted label from the neighbour pred_subgraph.nodes[ i].predicted_label = self.subgraph.nodes[ neighbour].predicted_label # Creating the list of predictions preds = [pred.predicted_label for pred in pred_subgraph.nodes] end = time.time() predict_time = end - start logger.info('Data has been predicted.') logger.info('Prediction time: %s seconds.', predict_time) return preds
def _learn(self, X_train, Y_train, I_train, X_val, Y_val, I_val): """Learns the best `k` value over the validation set. Args: X_train (np.array): Array of training features. Y_train (np.array): Array of training labels. I_train (np.array): Array of training indexes. X_val (np.array): Array of validation features. Y_val (np.array): Array of validation labels. I_val (np.array): Array of validation indexes. """ logger.info('Learning best `k` value ...') # Creating a subgraph self.subgraph = KNNSubgraph(X_train, Y_train, I_train) if self.pre_computed_distance: if self.pre_distances.shape[ 0] != self.subgraph.n_nodes or self.pre_distances.shape[ 1] != self.subgraph.n_nodes: raise e.BuildError( 'Pre-computed distance matrix should have the size of `n_nodes x n_nodes`' ) # Defining initial maximum accuracy as 0 max_acc = 0.0 for k in range(1, self.max_k + 1): # Gathers current `k` as subgraph's best `k` self.subgraph.best_k = k # Calculate the arcs using the current `k` value self.subgraph.create_arcs(k, self.distance_fn, self.pre_computed_distance, self.pre_distances) # Calculate the p.d.f. using the current `k` value self.subgraph.calculate_pdf(k, self.distance_fn, self.pre_computed_distance, self.pre_distances) # Clusters the subgraph self._clustering() # Calculate the predictions over the validation set preds = self.predict(X_val, I_val) # Calculating the accuracy acc = g.opf_accuracy(Y_val, preds) if acc > max_acc: max_acc = acc best_k = k logger.info('Accuracy over k = %d: %s', k, acc) self.subgraph.destroy_arcs() self.subgraph.best_k = best_k
import opfython.stream.loader as l import opfython.stream.parser as p from opfython.subgraphs import KNNSubgraph # Defining an input file input_file = 'data/boat.txt' # Loading a .txt file to a dataframe txt = l.load_txt(input_file) # Parsing a pre-loaded dataframe X, Y = p.parse_loader(txt) # Creating a knn-subgraph structure g = KNNSubgraph(X, Y) # KNNSubgraph can also be directly created from a file g = KNNSubgraph(from_file=input_file)
def predict(self, X_val, I_val=None): """Predicts new data using the pre-trained classifier. Args: X_val (np.array): Array of validation features. I_val (np.array): Array of validation indexes. Returns: A list of predictions for each record of the data. """ # Checks if there is a knn-subgraph if not self.subgraph: # If not, raises an BuildError raise e.BuildError('KNNSubgraph has not been properly created') # Checks if knn-subgraph has been properly trained if not self.subgraph.trained: # If not, raises an BuildError raise e.BuildError('Classifier has not been properly clustered') logger.info('Predicting data ...') # Initializing the timer start = time.time() # Creating a prediction subgraph pred_subgraph = KNNSubgraph(X_val, I=I_val) # Gathering the best `k` value best_k = self.subgraph.best_k # Creating an array of distances distances = np.zeros(best_k + 1) # Creating an array of nearest neighbours indexes neighbours_idx = np.zeros(best_k + 1) # For every possible prediction node for i in range(pred_subgraph.n_nodes): # Defines the current cost cost = -c.FLOAT_MAX # Filling array of distances with maximum value distances.fill(c.FLOAT_MAX) # For every possible trained node for j in range(self.subgraph.n_nodes): # If they are different nodes if j != i: # If it is supposed to use a pre-computed distance if self.pre_computed_distance: # Gathers the distance from the matrix distances[best_k] = self.pre_distances[ pred_subgraph.nodes[i].idx][ self.subgraph.nodes[j].idx] # If it is supposed to calculate the distance else: # Calculates the distance between nodes `i` and `j` distances[best_k] = self.distance_fn( pred_subgraph.nodes[i].features, self.subgraph.nodes[j].features) # Apply node `j` as a neighbour neighbours_idx[best_k] = j # Gathers current `k` cur_k = best_k # While current `k` is bigger than 0 and the `k` distance is smaller than `k-1` distance while cur_k > 0 and distances[cur_k] < distances[cur_k - 1]: # Swaps the distance from `k` and `k-1` distances[cur_k], distances[cur_k - 1] = distances[ cur_k - 1], distances[cur_k] # Swaps the neighbours indexex from `k` and `k-1` neighbours_idx[cur_k], neighbours_idx[ cur_k - 1] = neighbours_idx[cur_k - 1], neighbours_idx[cur_k] # Decrements `k` cur_k -= 1 # Defining the density as 0 density = 0.0 # For every possible k for k in range(best_k): # Accumulates the density density += np.exp(-distances[k] / self.subgraph.constant) # Gather its mean value density /= best_k # Scale the density between minimum and maximum values density = ((c.MAX_DENSITY - 1) * (density - self.subgraph.min_density) / (self.subgraph.max_density - self.subgraph.min_density + c.EPSILON)) + 1 # For every possible k for k in range(best_k): # If distance is different than maximum possible value if distances[k] != c.FLOAT_MAX: # Gathers the node's neighbour neighbour = int(neighbours_idx[k]) # Calculate the temporary cost temp_cost = np.minimum(self.subgraph.nodes[neighbour].cost, density) # If temporary cost is bigger than current cost if temp_cost > cost: # Replaces the current cost cost = temp_cost # Propagates the predicted label from the neighbour pred_subgraph.nodes[ i].predicted_label = self.subgraph.nodes[ neighbour].predicted_label # Propagates the cluster label from the neighbour pred_subgraph.nodes[ i].cluster_label = self.subgraph.nodes[ neighbour].cluster_label # Creating the list of predictions preds = [pred.predicted_label for pred in pred_subgraph.nodes] # Creating the list of clusters clusters = [pred.cluster_label for pred in pred_subgraph.nodes] # Ending timer end = time.time() # Calculating prediction task time predict_time = end - start logger.info('Data has been predicted.') logger.info('Prediction time: %s seconds.', predict_time) return preds, clusters
def _learn(self, X_train, Y_train, X_val, Y_val): """Learns the best `k` value over the validation set. Args: X_train (np.array): Array of training features. Y_train (np.array): Array of training labels. X_val (np.array): Array of validation features. Y_val (np.array): Array of validation labels. """ logger.info('Learning best `k` value ...') # Creating a subgraph self.subgraph = KNNSubgraph(X_train, Y_train) # Checks if it is supposed to use pre-computed distances if self.pre_computed_distance: # Checks if its size is the same as the subgraph's amount of nodes if self.pre_distances.shape[ 0] != self.subgraph.n_nodes or self.pre_distances.shape[ 1] != self.subgraph.n_nodes: # If not, raises an error raise e.BuildError( 'Pre-computed distance matrix should have the size of `n_nodes x n_nodes`' ) # Defining initial maximum accuracy as 0 max_acc = 0.0 # For every possible `k` value for k in range(1, self.max_k + 1): # Gathers current `k` as subgraph's best `k` self.subgraph.best_k = k # Calculate the arcs using the current `k` value self.subgraph.create_arcs(k, self.distance_fn, self.pre_computed_distance, self.pre_distances) # Calculate the p.d.f. using the current `k` value self.subgraph.calculate_pdf(k, self.distance_fn, self.pre_computed_distance, self.pre_distances) # Clusters the subgraph self._clustering() # Calculate the predictions over the validation set preds = self.predict(X_val) # Calculating the accuracy acc = g.opf_accuracy(Y_val, preds) # If accuracy is better than maximum accuracy if acc > max_acc: # Replaces the maximum accuracy value max_acc = acc # Defines current `k` as the best `k` value best_k = k logger.info(f'Accuracy over k = {k}: {acc}') # Destroy the arcs self.subgraph.destroy_arcs() # Applying the best k to the subgraph's property self.subgraph.best_k = best_k