import six import math import numpy as np from numba import jit from .bbox import * from .mask import * @jit def generate_rpn_anchor_target(anchors, gt_boxes, is_crowd, im_info, rpn_straddle_thresh, rpn_batch_size_per_im, rpn_positive_overlap, rpn_negative_overlap, rpn_fg_fraction, use_random=True, anchor_reg_weights=[1., 1., 1., 1.]): anchor_num = anchors.shape[0] batch_size = gt_boxes.shape[0] loc_indexes = [] cls_indexes = [] tgt_labels = [] tgt_deltas = [] anchor_inside_weights = [] for i in range(batch_size): # TODO: move anchor filter into anchor generator im_height = im_info[i][0] im_width = im_info[i][1] im_scale = im_info[i][2] if rpn_straddle_thresh >= 0: anchor_inds = np.where((anchors[:, 0] >= -rpn_straddle_thresh) & ( anchors[:, 1] >= -rpn_straddle_thresh) & ( anchors[:, 2] < im_width + rpn_straddle_thresh) & ( anchors[:, 3] < im_height + rpn_straddle_thresh))[0] anchor = anchors[anchor_inds, :] else: anchor_inds = np.arange(anchors.shape[0]) anchor = anchors gt_bbox = gt_boxes[i] * im_scale is_crowd_slice = is_crowd[i] not_crowd_inds = np.where(is_crowd_slice == 0)[0] gt_bbox = gt_bbox[not_crowd_inds] # Step1: match anchor and gt_bbox anchor_gt_bbox_inds, anchor_gt_bbox_iou, labels = label_anchor(anchor, gt_bbox) # Step2: sample anchor fg_inds, bg_inds, fg_fake_inds, fake_num = sample_anchor( anchor_gt_bbox_iou, labels, rpn_positive_overlap, rpn_negative_overlap, rpn_batch_size_per_im, rpn_fg_fraction, use_random) # Step3: make output loc_inds = np.hstack([fg_fake_inds, fg_inds]) cls_inds = np.hstack([fg_inds, bg_inds]) sampled_labels = labels[cls_inds] sampled_anchors = anchor[loc_inds] sampled_gt_boxes = gt_bbox[anchor_gt_bbox_inds[loc_inds]] sampled_deltas = bbox2delta(sampled_anchors, sampled_gt_boxes, anchor_reg_weights) anchor_inside_weight = np.zeros((len(loc_inds), 4), dtype=np.float32) anchor_inside_weight[fake_num:, :] = 1 loc_indexes.append(anchor_inds[loc_inds] + i * anchor_num) cls_indexes.append(anchor_inds[cls_inds] + i * anchor_num) tgt_labels.append(sampled_labels) tgt_deltas.append(sampled_deltas) anchor_inside_weights.append(anchor_inside_weight) loc_indexes = np.concatenate(loc_indexes) cls_indexes = np.concatenate(cls_indexes) tgt_labels = np.concatenate(tgt_labels).astype('float32') tgt_deltas = np.vstack(tgt_deltas).astype('float32') anchor_inside_weights = np.vstack(anchor_inside_weights) return loc_indexes, cls_indexes, tgt_labels, tgt_deltas, anchor_inside_weights @jit def label_anchor(anchors, gt_boxes): iou = compute_iou(anchors, gt_boxes) # every gt's anchor's index gt_bbox_anchor_inds = iou.argmax(axis=0) gt_bbox_anchor_iou = iou[gt_bbox_anchor_inds, np.arange(iou.shape[1])] gt_bbox_anchor_iou_inds = np.where(iou == gt_bbox_anchor_iou)[0] # every anchor's gt bbox's index anchor_gt_bbox_inds = iou.argmax(axis=1) anchor_gt_bbox_iou = iou[np.arange(iou.shape[0]), anchor_gt_bbox_inds] labels = np.ones((iou.shape[0], ), dtype=np.int32) * -1 labels[gt_bbox_anchor_iou_inds] = 1 return anchor_gt_bbox_inds, anchor_gt_bbox_iou, labels @jit def sample_anchor(anchor_gt_bbox_iou, labels, rpn_positive_overlap, rpn_negative_overlap, rpn_batch_size_per_im, rpn_fg_fraction, use_random=True): labels[anchor_gt_bbox_iou >= rpn_positive_overlap] = 1 num_fg = int(rpn_fg_fraction * rpn_batch_size_per_im) fg_inds = np.where(labels == 1)[0] if len(fg_inds) > num_fg and use_random: disable_inds = np.random.choice( fg_inds, size=(len(fg_inds) - num_fg), replace=False) else: disable_inds = fg_inds[num_fg:] labels[disable_inds] = -1 fg_inds = np.where(labels == 1)[0] num_bg = rpn_batch_size_per_im - np.sum(labels == 1) bg_inds = np.where(anchor_gt_bbox_iou < rpn_negative_overlap)[0] if len(bg_inds) > num_bg and use_random: enable_inds = bg_inds[np.random.randint(len(bg_inds), size=num_bg)] else: enable_inds = bg_inds[:num_bg] fg_fake_inds = np.array([], np.int32) fg_value = np.array([fg_inds[0]], np.int32) fake_num = 0 for bg_id in enable_inds: if bg_id in fg_inds: fake_num += 1 fg_fake_inds = np.hstack([fg_fake_inds, fg_value]) labels[enable_inds] = 0 fg_inds = np.where(labels == 1)[0] bg_inds = np.where(labels == 0)[0] return fg_inds, bg_inds, fg_fake_inds, fake_num @jit def generate_proposal_target(rpn_rois, rpn_rois_nums, gt_classes, is_crowd, gt_boxes, im_info, batch_size_per_im, fg_fraction, fg_thresh, bg_thresh_hi, bg_thresh_lo, bbox_reg_weights, class_nums=81, use_random=True, is_cls_agnostic=False, is_cascade_rcnn=False): rois = [] tgt_labels = [] tgt_deltas = [] rois_inside_weights = [] rois_outside_weights = [] rois_nums = [] st_num = 0 end_num = 0 for im_i in range(len(rpn_rois_nums)): rpn_rois_num = rpn_rois_nums[im_i] end_num += rpn_rois_num rpn_roi = rpn_rois[st_num:end_num] im_scale = im_info[im_i][2] rpn_roi = rpn_roi / im_scale gt_bbox = gt_boxes[im_i] if is_cascade_rcnn: rpn_roi = rpn_roi[gt_bbox.shape[0]:, :] bbox = np.vstack([gt_bbox, rpn_roi]) # Step1: label bbox roi_gt_bbox_inds, roi_gt_bbox_iou, labels, = label_bbox( bbox, gt_bbox, gt_classes[im_i], is_crowd[im_i]) # Step2: sample bbox if is_cascade_rcnn: ws = bbox[:, 2] - bbox[:, 0] + 1 hs = bbox[:, 3] - bbox[:, 1] + 1 keep = np.where((ws > 0) & (hs > 0))[0] bbox = bbox[keep] fg_inds, bg_inds, fg_nums = sample_bbox( roi_gt_bbox_iou, batch_size_per_im, fg_fraction, fg_thresh, bg_thresh_hi, bg_thresh_lo, bbox_reg_weights, class_nums, use_random, is_cls_agnostic, is_cascade_rcnn) # Step3: make output sampled_inds = np.append(fg_inds, bg_inds) sampled_labels = labels[sampled_inds] sampled_labels[fg_nums:] = 0 sampled_boxes = bbox[sampled_inds] sampled_gt_boxes = gt_bbox[roi_gt_bbox_inds[sampled_inds]] sampled_gt_boxes[fg_nums:, :] = gt_bbox[0] sampled_deltas = compute_bbox_targets(sampled_boxes, sampled_gt_boxes, sampled_labels, bbox_reg_weights) sampled_deltas, bbox_inside_weights = expand_bbox_targets( sampled_deltas, class_nums, is_cls_agnostic) bbox_outside_weights = np.array( bbox_inside_weights > 0, dtype=bbox_inside_weights.dtype) roi = sampled_boxes * im_scale st_num += rpn_rois_num rois.append(roi) rois_nums.append(roi.shape[0]) tgt_labels.append(sampled_labels) tgt_deltas.append(sampled_deltas) rois_inside_weights.append(bbox_inside_weights) rois_outside_weights.append(bbox_outside_weights) rois = np.concatenate(rois, axis=0).astype(np.float32) tgt_labels = np.concatenate( tgt_labels, axis=0).astype(np.int32).reshape(-1, 1) tgt_deltas = np.concatenate(tgt_deltas, axis=0).astype(np.float32) rois_inside_weights = np.concatenate( rois_inside_weights, axis=0).astype(np.float32) rois_outside_weights = np.concatenate( rois_outside_weights, axis=0).astype(np.float32) rois_nums = np.asarray(rois_nums, np.int32) return rois, tgt_labels, tgt_deltas, rois_inside_weights, rois_outside_weights, rois_nums @jit def label_bbox(boxes, gt_boxes, gt_classes, is_crowd, class_nums=81, is_cascade_rcnn=False): iou = compute_iou(boxes, gt_boxes) # every roi's gt box's index roi_gt_bbox_inds = np.zeros((boxes.shape[0]), dtype=np.int32) roi_gt_bbox_iou = np.zeros((boxes.shape[0], class_nums)) iou_argmax = iou.argmax(axis=1) iou_max = iou.max(axis=1) overlapped_boxes_ind = np.where(iou_max > 0)[0].astype('int32') roi_gt_bbox_inds[overlapped_boxes_ind] = iou_argmax[overlapped_boxes_ind] overlapped_boxes_gt_classes = gt_classes[iou_argmax[ overlapped_boxes_ind]].astype('int32') roi_gt_bbox_iou[overlapped_boxes_ind, overlapped_boxes_gt_classes] = iou_max[overlapped_boxes_ind] crowd_ind = np.where(is_crowd)[0] roi_gt_bbox_iou[crowd_ind] = -1 labels = roi_gt_bbox_iou.argmax(axis=1) return roi_gt_bbox_inds, roi_gt_bbox_iou, labels @jit def sample_bbox(roi_gt_bbox_iou, batch_size_per_im, fg_fraction, fg_thresh, bg_thresh_hi, bg_thresh_lo, bbox_reg_weights, class_nums, use_random=True, is_cls_agnostic=False, is_cascade_rcnn=False): roi_gt_bbox_iou_max = roi_gt_bbox_iou.max(axis=1) rois_per_image = int(batch_size_per_im) fg_rois_per_im = int(np.round(fg_fraction * rois_per_image)) if is_cascade_rcnn: fg_inds = np.where(roi_gt_bbox_iou_max >= fg_thresh)[0] bg_inds = np.where((roi_gt_bbox_iou_max < bg_thresh_hi) & ( roi_gt_bbox_iou_max >= bg_thresh_lo))[0] fg_nums = fg_inds.shape[0] bg_nums = bg_inds.shape[0] else: # sampe fg fg_inds = np.where(roi_gt_bbox_iou_max >= fg_thresh)[0] fg_nums = np.minimum(fg_rois_per_im, fg_inds.shape[0]) if (fg_inds.shape[0] > fg_nums) and use_random: fg_inds = np.random.choice(fg_inds, size=fg_nums, replace=False) fg_inds = fg_inds[:fg_nums] # sample bg bg_inds = np.where((roi_gt_bbox_iou_max < bg_thresh_hi) & ( roi_gt_bbox_iou_max >= bg_thresh_lo))[0] bg_nums = rois_per_image - fg_nums bg_nums = np.minimum(bg_nums, bg_inds.shape[0]) if (bg_inds.shape[0] > bg_nums) and use_random: bg_inds = np.random.choice(bg_inds, size=bg_nums, replace=False) bg_inds = bg_inds[:bg_nums] return fg_inds, bg_inds, fg_nums @jit def generate_mask_target(im_info, gt_classes, is_crowd, gt_segms, rois, rois_nums, labels_int32, num_classes, resolution): mask_rois = [] rois_has_mask_int32 = [] mask_int32 = [] st_num = 0 end_num = 0 for k in range(len(rois_nums)): rois_num = rois_nums[k] end_num += rois_num # remove padding gt_polys = gt_segms[k] new_gt_polys = [] for i in range(gt_polys.shape[0]): gt_segs = [] for j in range(gt_polys[i].shape[0]): new_poly = [] polys = gt_polys[i][j] for ii in range(polys.shape[0]): x, y = polys[ii] if (x == -1 and y == -1): continue elif (x >= 0 and y >= 0): new_poly.append([x, y]) # array, one poly if len(new_poly) > 0: gt_segs.append(new_poly) new_gt_polys.append(gt_segs) im_scale = im_info[k][2] boxes = rois[st_num:end_num] / im_scale bbox_fg, bbox_has_mask, masks = sample_mask( boxes, new_gt_polys, labels_int32[st_num:rois_num], gt_classes[k], is_crowd[k], num_classes, resolution) st_num += rois_num mask_rois.append(bbox_fg * im_scale) rois_has_mask_int32.append(bbox_has_mask) mask_int32.append(masks) mask_rois = np.concatenate(mask_rois, axis=0).astype(np.float32) rois_has_mask_int32 = np.concatenate( rois_has_mask_int32, axis=0).astype(np.int32) mask_int32 = np.concatenate(mask_int32, axis=0).astype(np.int32) return mask_rois, rois_has_mask_int32, mask_int32 @jit def sample_mask( boxes, gt_polys, label_int32, gt_classes, is_crowd, num_classes, resolution, ): gt_polys_inds = np.where((gt_classes > 0) & (is_crowd == 0))[0] _gt_polys = [gt_polys[i] for i in gt_polys_inds] boxes_from_polys = polys_to_boxes(_gt_polys) fg_inds = np.where(label_int32 > 0)[0] bbox_has_mask = fg_inds.copy() if fg_inds.shape[0] > 0: labels_fg = label_int32[fg_inds] masks_fg = np.zeros((fg_inds.shape[0], resolution**2), dtype=np.int32) bbox_fg = boxes[fg_inds] iou = bbox_overlaps_mask(bbox_fg, boxes_from_polys) fg_polys_inds = np.argmax(iou, axis=1) for i in range(bbox_fg.shape[0]): poly_gt = _gt_polys[fg_polys_inds[i]] roi_fg = bbox_fg[i] mask = polys_to_mask_wrt_box(poly_gt, roi_fg, resolution) mask = np.array(mask > 0, dtype=np.int32) masks_fg[i, :] = np.reshape(mask, resolution**2) else: bg_inds = np.where(label_int32 == 0)[0] bbox_fg = boxes[bg_inds[0]].reshape((1, -1)) masks_fg = -np.ones((1, resolution**2), dtype=np.int32) labels_fg = np.zeros((1, )) bbox_has_mask = np.append(bbox_has_mask, 0) masks = expand_mask_targets(masks_fg, labels_fg, resolution, num_classes) return bbox_fg, bbox_has_mask, masks