py-faster-rcnn代码阅读3-roidb.py
roidb是比较复杂的数据结构,存放了数据集的roi信息。原始的roidb来自数据集,在trian.py的get_training_roidb(imdb)函数进行了水平翻转扩充数量,然后prepare_roidb(imdb)【定义在roidb.py】为roidb添加了一些说明性的属性。
在这里暂时记录下roidb的结构信息,后面继续看的时候可能会有些修正:
roidb是由字典组成的list,roidb[img_index]包含了该图片索引所包含到roi信息,下面以roidb[img_index]为例说明:
| roidb[img_index]包含的key, | value |
| boxes | box位置信息,box_num*4的np array |
| gt_overlaps | 所有box在不同类别的得分,box_num*class_num矩阵 |
| gt_classes | 所有box的真实类别,box_num长度的list |
| flipped | 是否翻转 |
| image | 该图片的路径,字符串 |
| width | 图片的宽 |
| height | 图片的高 |
| max_overlaps | 每个box的在所有类别的得分最大值,box_num长度 |
| max_classes | 每个box的得分最高所对应的类,box_num长度 |
| bbox_targets | 每个box的类别,以及与最接近的gt-box的4个方位偏移 |
参考iamzhangzhuping的博客,感谢!更多信息请移步iamzhangzhuping的博客
下面是代码
roidb.py import numpy as np from fast_rcnn.config import cfg from fast_rcnn.bbox_transform import bbox_transform from utils.cython_bbox import bbox_overlaps import PIL def prepare_roidb(imdb): # 给原始roidata添加一些说明性的附加属性 """Enrich the imdb's roidb by adding some derived quantities that are useful for training. This function precomputes the maximum overlap, taken over ground-truth boxes, between each ROI and each ground-truth box. The class with maximum overlap is also recorded. """ sizes = [PIL.Image.open(imdb.image_path_at(i)).size for i in xrange(imdb.num_images)] # 当在‘Stage 2 Fast R-CNN, init from stage 2 RPN R-CNN model’阶段中,roidb由rpn_roidb() # 方法生成,其中的每一张图像的box不仅仅只有gtbox,还包括rpn_file里面的box。 roidb = imdb.roidb for i in xrange(len(imdb.image_index)): roidb[i]['image'] = imdb.image_path_at(i) roidb[i]['width'] = sizes[i][0] roidb[i]['height'] = sizes[i][1] # need gt_overlaps as a dense array for argmax # gt_overlaps是一个box_num*classes_num的矩阵,应该是每个box在不同类别的得分 gt_overlaps = roidb[i]['gt_overlaps'].toarray() # max overlap with gt over classes (columns) # 每个box的在所有类别的得分最大值,box_num长度 max_overlaps = gt_overlaps.max(axis=1) # gt class that had the max overlap # 每个box的得分最高所对应的类,box_num长度 max_classes = gt_overlaps.argmax(axis=1) roidb[i]['max_classes'] = max_classes roidb[i]['max_overlaps'] = max_overlaps # sanity checks # 做检查,max_overlaps == 0意味着背景,否则非背景 # max overlap of 0 => class should be zero (background) zero_inds = np.where(max_overlaps == 0)[0] assert all(max_classes[zero_inds] == 0) # max overlap > 0 => class should not be zero (must be a fg class) nonzero_inds = np.where(max_overlaps > 0)[0] assert all(max_classes[nonzero_inds] != 0) def add_bbox_regression_targets(roidb): """Add information needed to train bounding-box regressors.""" assert len(roidb) > 0 assert 'max_classes' in roidb[0], 'Did you call prepare_roidb first?' num_images = len(roidb) # Infer number of classes from the number of columns in gt_overlaps # 类别数,roidb[0]对应第0号图片上的roi,shape[1]多少列表示roi属于不同类上的概率 num_classes = roidb[0]['gt_overlaps'].shape[1] for im_i in xrange(num_images): rois = roidb[im_i]['boxes'] max_overlaps = roidb[im_i]['max_overlaps'] max_classes = roidb[im_i]['max_classes'] # bbox_targets:每个box的类别,以及与最接近的gt-box的4个方位偏移 roidb[im_i]['bbox_targets'] = \ _compute_targets(rois, max_overlaps, max_classes) # 这里config是false if cfg.TRAIN.BBOX_NORMALIZE_TARGETS_PRECOMPUTED: # Use fixed / precomputed "means" and "stds" instead of empirical values # 使用固定的均值和方差代替经验值 means = np.tile( np.array(cfg.TRAIN.BBOX_NORMALIZE_MEANS), (num_classes, 1)) stds = np.tile( np.array(cfg.TRAIN.BBOX_NORMALIZE_STDS), (num_classes, 1)) else: # Compute values needed for means and stds # 计算所需的均值和方差 # var(x) = E(x^2) - E(x)^2 # 计数各个类别出现box的数量 class_counts = np.zeros((num_classes, 1)) + cfg.EPS #加上cfg.EPS防止除0出错 # 21类*4个位置,如果出现box的类别与其中某一类相同,将该box的4个target加入4个列元素中 sums = np.zeros((num_classes, 4)) # 21类*4个位置,如果出现box的类别与其中某一类相同,将该box的4个target的平方加入4个列元素中 squared_sums = np.zeros((num_classes, 4)) for im_i in xrange(num_images): targets = roidb[im_i]['bbox_targets'] for cls in xrange(1, num_classes): cls_inds = np.where(targets[:, 0] == cls)[0] # box的类别与该类匹配,计入 if cls_inds.size > 0: class_counts[cls] += cls_inds.size sums[cls, :] += targets[cls_inds, 1:].sum(axis=0) squared_sums[cls, :] += \ (targets[cls_inds, 1:] ** 2).sum(axis=0) means = sums / class_counts # 均值 stds = np.sqrt(squared_sums / class_counts - means ** 2) #标准差 print 'bbox target means:' print means print means[1:, :].mean(axis=0) # ignore bg class print 'bbox target stdevs:' print stds print stds[1:, :].mean(axis=0) # ignore bg class # Normalize targets # 对每一box归一化target if cfg.TRAIN.BBOX_NORMALIZE_TARGETS: print "Normalizing targets" for im_i in xrange(num_images): targets = roidb[im_i]['bbox_targets'] for cls in xrange(1, num_classes): cls_inds = np.where(targets[:, 0] == cls)[0] roidb[im_i]['bbox_targets'][cls_inds, 1:] -= means[cls, :] roidb[im_i]['bbox_targets'][cls_inds, 1:] /= stds[cls, :] else: print "NOT normalizing targets" # 均值和方差也用于预测 # These values will be needed for making predictions # (the predicts will need to be unnormalized and uncentered) return means.ravel(), stds.ravel() # ravel()排序拉成一维 def _compute_targets(rois, overlaps, labels): # 参数rois只含有当前图片的box信息 """Compute bounding-box regression targets for an image.""" # Indices目录 of ground-truth ROIs # ground-truth ROIs gt_inds = np.where(overlaps == 1)[0] if len(gt_inds) == 0: # Bail if the image has no ground-truth ROIs # 不存在gt ROI,返回空数组 return np.zeros((rois.shape[0], 5), dtype=np.float32) # Indices of examples for which we try to make predictions # BBOX阈值,只有ROI与gt的重叠度大于阈值,这样的ROI才能用作bb回归的训练样本 ex_inds = np.where(overlaps >= cfg.TRAIN.BBOX_THRESH)[0] # Get IoU overlap between each ex ROI and gt ROI # 计算ex ROI and gt ROI的IoU ex_gt_overlaps = bbox_overlaps( # 变数据格式为float np.ascontiguousarray(rois[ex_inds, :], dtype=np.float), np.ascontiguousarray(rois[gt_inds, :], dtype=np.float)) # Find which gt ROI each ex ROI has max overlap with: # this will be the ex ROI's gt target # 这里每一行代表一个ex_roi,列代表gt_roi,元素数值代表两者的IoU gt_assignment = ex_gt_overlaps.argmax(axis=1) #按行求最大,返回索引. gt_rois = rois[gt_inds[gt_assignment], :] #每个ex_roi对应的gt_rois,与下面ex_roi数量相同 ex_rois = rois[ex_inds, :] targets = np.zeros((rois.shape[0], 5), dtype=np.float32) targets[ex_inds, 0] = labels[ex_inds] #第一个元素是label targets[ex_inds, 1:] = bbox_transform(ex_rois, gt_rois) #后4个元素是ex_box与gt_box的4个方位的偏移 return targets
