# Author:LiPu import numpy as np import pandas as pd import os class YOLO_Kmeans: def __init__(self, cluster_number, data_file, anchors_file): self.cluster_number = cluster_number # 6 or 9 self.data_file = data_file self.anchors_file = anchors_file def iou(self, boxes, clusters): # 1 box -> k clusters, boxes代表实际的每个box的宽和高, clusters为聚类中心 n = boxes.shape[0] k = self.cluster_number box_area = boxes[:, 0] * boxes[:, 1] # box的面积长x宽 box_area = box_area.repeat(k) # 将每个box的面积重复6次,构成一个1行6列的数组 box_area = np.reshape(box_area, (n, k)) cluster_area = clusters[:, 0] * clusters[:, 1] # 计算每个聚类中心的面积 cluster_area = np.tile(cluster_area, [1, n]) cluster_area = np.reshape(cluster_area, (n, k)) # 将聚类中心构成与输入boxes具有同样维度的矩阵,可以避免循环运算 box_w_matrix = np.reshape(boxes[:, 0].repeat(k), (n, k)) cluster_w_matrix = np.reshape(np.tile(clusters[:, 0], (1, n)), (n, k)) min_w_matrix = np.minimum(cluster_w_matrix, box_w_matrix) box_h_matrix = np.reshape(boxes[:, 1].repeat(k), (n, k)) cluster_h_matrix = np.reshape(np.tile(clusters[:, 1], (1, n)), (n, k)) min_h_matrix = np.minimum(cluster_h_matrix, box_h_matrix) inter_area = np.multiply(min_w_matrix, min_h_matrix) result = inter_area / (box_area + cluster_area - inter_area) return result def avg_iou(self, boxes, clusters): accuracy = np.mean([np.max(self.iou(boxes, clusters), axis=1)]) return accuracy def kmeans(self, boxes, k, dist=np.median): box_number = boxes.shape[0] distances = np.empty((box_number, k)) last_nearest = np.zeros((box_number,)) np.random.seed() clusters = boxes[np.random.choice( box_number, k, replace=False)] # init k clusters从原来的众多box中随机选取6个box while True: distances = 1 - self.iou(boxes, clusters) current_nearest = np.argmin(distances, axis=1) if (last_nearest == current_nearest).all(): break # clusters won't change for cluster in range(k): clusters[cluster] = dist( # update clusters boxes[current_nearest == cluster], axis=0) last_nearest = current_nearest return clusters def result2txt(self, data): # 将data保存进txt文档中,覆盖方式 f = open(self.anchors_file, 'w') row = np.shape(data)[0] for i in range(row): if i == 0: x_y = "%d,%d" % (data[i][0], data[i][1]) # 若data只有1行,直接两个数据用逗号隔开保存 else: x_y = ", %d,%d" % (data[i][0], data[i][1]) # 若data有多行,就将每行数据以空格隔开 f.write(x_y) f.close() def txt2boxes(self): test = os.listdir(self.data_file + 'test/') train = os.listdir(self.data_file + 'train/') dataSet = [] for i in train: f = open(self.data_file + 'train/' + i, 'r') for line in f: infos = line.split(" ") width = int(float(infos[3]) * 416) height = int(float(infos[4]) * 416) dataSet.append([width, height]) f.close() for i in test: f = open(self.data_file + 'test/' + i, 'r') for line in f: infos = line.split(" ") width = int(float(infos[3]) * 416) height = int(float(infos[4]) * 416) dataSet.append([width, height]) f.close() result = np.array(dataSet) return result def csv2boxes(self): dataSet = [] train_data = pd.read_csv(self.data_file, header=None) for value_i in train_data.values: end_num = len(value_i) for i in range(1, end_num, 5): width = value_i[i + 2] - value_i[i] height = value_i[i + 3] - value_i[i + 1] dataSet.append([width, height]) ##获取所有box的宽和高 result = np.array(dataSet) return result def txt2clusters(self): # all_boxes = self.csv2boxes() # 获取所有box的宽和高 all_boxes = self.txt2boxes() result = self.kmeans(all_boxes, k=self.cluster_number) result = result[np.lexsort(result.T[0, None])] # 对于聚类结果,按照第一维度进行从小到大排序 self.result2txt(result) print("K anchors:\n {}".format(result)) print("Accuracy: {:.2f}%".format( self.avg_iou(all_boxes, result) * 100)) if __name__ == "__main__": cluster_number = 6 # tiny-yolo--6, yolo--9 data_file = "labels/" anchors_file = "anchors_6.txt" kmeans = YOLO_Kmeans(cluster_number=cluster_number, data_file=data_file, anchors_file=anchors_file) kmeans.txt2clusters()