def prep_pointcloud(input_dict, root_path, voxel_generator, target_assigner, db_sampler=None, max_voxels=20000, class_names=['Car'], remove_outside_points=False, training=True, create_targets=True, shuffle_points=False, reduce_valid_area=False, remove_unknown=False, gt_rotation_noise=[-np.pi / 3, np.pi / 3], gt_loc_noise_std=[1.0, 1.0, 1.0], global_rotation_noise=[-np.pi / 4, np.pi / 4], global_scaling_noise=[0.95, 1.05], global_random_rot_range=[0.78, 2.35], generate_bev=False, without_reflectivity=False, num_point_features=4, anchor_area_threshold=1, gt_points_drop=0.0, gt_drop_max_keep=10, remove_points_after_sample=True, anchor_cache=None, remove_environment=False, random_crop=False, reference_detections=None, add_rgb_to_points=False, lidar_input=False, unlabeled_db_sampler=None, out_size_factor=2, min_gt_point_dict=None, bev_only=False, use_group_id=False, out_dtype=np.float32): """convert point cloud to voxels, create targets if ground truths exists. """ points = input_dict["points"] if training: gt_boxes = input_dict["gt_boxes"] gt_names = input_dict["gt_names"] difficulty = input_dict["difficulty"] group_ids = None if use_group_id and "group_ids" in input_dict: group_ids = input_dict["group_ids"] rect = input_dict["rect"] Trv2c = input_dict["Trv2c"] P2 = input_dict["P2"] unlabeled_training = unlabeled_db_sampler is not None #image_idx = input_dict["image_idx"] if reference_detections is not None: C, R, T = box_np_ops.projection_matrix_to_CRT_kitti(P2) frustums = box_np_ops.get_frustum_v2(reference_detections, C) frustums -= T # frustums = np.linalg.inv(R) @ frustums.T frustums = np.einsum('ij, akj->aki', np.linalg.inv(R), frustums) frustums = box_np_ops.camera_to_lidar(frustums, rect, Trv2c) surfaces = box_np_ops.corner_to_surfaces_3d_jit(frustums) masks = points_in_convex_polygon_3d_jit(points, surfaces) points = points[masks.any(-1)] if remove_outside_points and not lidar_input: image_shape = input_dict["image_shape"] points = box_np_ops.remove_outside_points(points, rect, Trv2c, P2, image_shape) if remove_environment is True and training: selected = kitti.keep_arrays_by_name(gt_names, class_names) gt_boxes = gt_boxes[selected] gt_names = gt_names[selected] difficulty = difficulty[selected] if group_ids is not None: group_ids = group_ids[selected] points = prep.remove_points_outside_boxes(points, gt_boxes) if training: # print(gt_names) selected = kitti.drop_arrays_by_name(gt_names, ["DontCare"]) gt_boxes = gt_boxes[selected] gt_names = gt_names[selected] difficulty = difficulty[selected] if group_ids is not None: group_ids = group_ids[selected] gt_boxes = box_np_ops.box_camera_to_lidar(gt_boxes, rect, Trv2c) if remove_unknown: remove_mask = difficulty == -1 """ gt_boxes_remove = gt_boxes[remove_mask] gt_boxes_remove[:, 3:6] += 0.25 points = prep.remove_points_in_boxes(points, gt_boxes_remove) """ keep_mask = np.logical_not(remove_mask) gt_boxes = gt_boxes[keep_mask] gt_names = gt_names[keep_mask] difficulty = difficulty[keep_mask] if group_ids is not None: group_ids = group_ids[keep_mask] gt_boxes_mask = np.array([n in class_names for n in gt_names], dtype=np.bool_) if db_sampler is not None: sampled_dict = db_sampler.sample_all(root_path, gt_boxes, gt_names, num_point_features, random_crop, gt_group_ids=group_ids, rect=rect, Trv2c=Trv2c, P2=P2) if sampled_dict is not None: sampled_gt_names = sampled_dict["gt_names"] sampled_gt_boxes = sampled_dict["gt_boxes"] sampled_points = sampled_dict["points"] sampled_gt_masks = sampled_dict["gt_masks"] # gt_names = gt_names[gt_boxes_mask].tolist() gt_names = np.concatenate([gt_names, sampled_gt_names], axis=0) # gt_names += [s["name"] for s in sampled] gt_boxes = np.concatenate([gt_boxes, sampled_gt_boxes]) gt_boxes_mask = np.concatenate( [gt_boxes_mask, sampled_gt_masks], axis=0) if group_ids is not None: sampled_group_ids = sampled_dict["group_ids"] group_ids = np.concatenate([group_ids, sampled_group_ids]) if remove_points_after_sample: points = prep.remove_points_in_boxes( points, sampled_gt_boxes) points = np.concatenate([sampled_points, points], axis=0) # unlabeled_mask = np.zeros((gt_boxes.shape[0], ), dtype=np.bool_) if without_reflectivity: used_point_axes = list(range(num_point_features)) used_point_axes.pop(3) points = points[:, used_point_axes] pc_range = voxel_generator.point_cloud_range if bev_only: # set z and h to limits gt_boxes[:, 2] = pc_range[2] gt_boxes[:, 5] = pc_range[5] - pc_range[2] prep.noise_per_object_v3_( gt_boxes, points, gt_boxes_mask, rotation_perturb=gt_rotation_noise, center_noise_std=gt_loc_noise_std, global_random_rot_range=global_random_rot_range, group_ids=group_ids, num_try=100) # should remove unrelated objects after noise per object gt_boxes = gt_boxes[gt_boxes_mask] gt_names = gt_names[gt_boxes_mask] if group_ids is not None: group_ids = group_ids[gt_boxes_mask] gt_classes = np.array([class_names.index(n) + 1 for n in gt_names], dtype=np.int32) gt_boxes, points = prep.random_flip(gt_boxes, points) gt_boxes, points = prep.global_rotation(gt_boxes, points, rotation=global_rotation_noise) gt_boxes, points = prep.global_scaling_v2(gt_boxes, points, *global_scaling_noise) bv_range = voxel_generator.point_cloud_range[[0, 1, 3, 4]] mask = prep.filter_gt_box_outside_range(gt_boxes, bv_range) gt_boxes = gt_boxes[mask] gt_classes = gt_classes[mask] gt_names = gt_names[mask] if group_ids is not None: group_ids = group_ids[mask] # limit rad to [-pi, pi] gt_boxes[:, 6] = box_np_ops.limit_period(gt_boxes[:, 6], offset=0.5, period=2 * np.pi) if shuffle_points: # shuffle is a little slow. np.random.shuffle(points) # [0, -40, -3, 70.4, 40, 1] voxel_size = voxel_generator.voxel_size pc_range = voxel_generator.point_cloud_range grid_size = voxel_generator.grid_size # [352, 400] voxels, coordinates, num_points = voxel_generator.generate( points, max_voxels) example = { 'voxels': voxels, 'num_points': num_points, 'coordinates': coordinates, "num_voxels": np.array([voxels.shape[0]], dtype=np.int64) } example.update({ 'rect': rect, 'Trv2c': Trv2c, 'P2': P2, }) # if not lidar_input: feature_map_size = grid_size[:2] // out_size_factor feature_map_size = [*feature_map_size, 1][::-1] if anchor_cache is not None: anchors = anchor_cache["anchors"] anchors_bv = anchor_cache["anchors_bv"] matched_thresholds = anchor_cache["matched_thresholds"] unmatched_thresholds = anchor_cache["unmatched_thresholds"] anchors_dict = anchor_cache["anchors_dict"] else: ret = target_assigner.generate_anchors(feature_map_size) anchors = ret["anchors"] anchors = anchors.reshape([-1, 7]) matched_thresholds = ret["matched_thresholds"] unmatched_thresholds = ret["unmatched_thresholds"] anchors_dict = target_assigner.generate_anchors_dict(feature_map_size) anchors_bv = box_np_ops.rbbox2d_to_near_bbox(anchors[:, [0, 1, 3, 4, 6]]) example["anchors"] = anchors # print("debug", anchors.shape, matched_thresholds.shape) # anchors_bv = anchors_bv.reshape([-1, 4]) anchors_mask = None if anchor_area_threshold >= 0: coors = coordinates dense_voxel_map = box_np_ops.sparse_sum_for_anchors_mask( coors, tuple(grid_size[::-1][1:])) dense_voxel_map = dense_voxel_map.cumsum(0) dense_voxel_map = dense_voxel_map.cumsum(1) anchors_area = box_np_ops.fused_get_anchors_area( dense_voxel_map, anchors_bv, voxel_size, pc_range, grid_size) anchors_mask = anchors_area > anchor_area_threshold # example['anchors_mask'] = anchors_mask.astype(np.uint8) example['anchors_mask'] = anchors_mask if not training: return example if create_targets: targets_dict = target_assigner.assign_v2(anchors_dict, gt_boxes, anchors_mask, gt_classes=gt_classes, gt_names=gt_names) example.update({ 'labels': targets_dict['labels'], 'reg_targets': targets_dict['bbox_targets'], 'reg_weights': targets_dict['bbox_outside_weights'], }) return example
def prep_pointcloud(input_dict, root_path, voxel_generator, target_assigner, db_sampler=None, max_voxels=20000, class_names=['Car'], remove_outside_points=False, training=True, create_targets=True, shuffle_points=False, reduce_valid_area=False, remove_unknown=False, gt_rotation_noise=[-np.pi / 3, np.pi / 3], gt_loc_noise_std=[1.0, 1.0, 1.0], global_rotation_noise=[-np.pi / 4, np.pi / 4], global_scaling_noise=[0.95, 1.05], global_loc_noise_std=(0.2, 0.2, 0.2), global_random_rot_range=[0.78, 2.35], generate_bev=False, without_reflectivity=False, num_point_features=4, anchor_area_threshold=1, gt_points_drop=0.0, gt_drop_max_keep=10, remove_points_after_sample=True, anchor_cache=None, remove_environment=False, random_crop=False, reference_detections=None, add_rgb_to_points=False, lidar_input=False, unlabeled_db_sampler=None, out_size_factor=2, min_gt_point_dict=None, bev_only=False, use_group_id=False, out_dtype=np.float32): """convert point cloud to voxels, create targets if ground truths exists. """ # 这部分用来读取某一帧数据 points = input_dict["points"] # velodyne_reduced, array(N*4) if training: gt_boxes = input_dict["gt_boxes"] # 真值框,位置,尺寸,绝对转角,N*1,一个真值框一行 gt_names = input_dict["gt_names"] difficulty = input_dict["difficulty"] group_ids = None if use_group_id and "group_ids" in input_dict: # False group_ids = input_dict["group_ids"] rect = input_dict["rect"] Trv2c = input_dict["Trv2c"] P2 = input_dict["P2"] unlabeled_training = unlabeled_db_sampler is not None image_idx = input_dict["image_idx"] if reference_detections is not None: # None C, R, T = box_np_ops.projection_matrix_to_CRT_kitti(P2) frustums = box_np_ops.get_frustum_v2(reference_detections, C) frustums -= T # frustums = np.linalg.inv(R) @ frustums.T frustums = np.einsum('ij, akj->aki', np.linalg.inv(R), frustums) frustums = box_np_ops.camera_to_lidar(frustums, rect, Trv2c) surfaces = box_np_ops.corner_to_surfaces_3d_jit(frustums) masks = points_in_convex_polygon_3d_jit(points, surfaces) points = points[masks.any(-1)] if remove_outside_points and not lidar_input: # False image_shape = input_dict["image_shape"] points = box_np_ops.remove_outside_points(points, rect, Trv2c, P2, image_shape) if remove_environment is True and training: # False selected = kitti.keep_arrays_by_name(gt_names, class_names) gt_boxes = gt_boxes[selected] gt_names = gt_names[selected] difficulty = difficulty[selected] if group_ids is not None: # None group_ids = group_ids[selected] points = prep.remove_points_outside_boxes(points, gt_boxes) if training: # 先去掉真值内的DontCare selected = kitti.drop_arrays_by_name(gt_names, ["DontCare"]) # 去掉DontCare gt_boxes = gt_boxes[selected] gt_names = gt_names[selected] difficulty = difficulty[selected] if group_ids is not None: # None group_ids = group_ids[selected] gt_boxes = box_np_ops.box_camera_to_lidar(gt_boxes, rect, Trv2c) # 相机坐标下的真值框转换成激光雷达坐标下[xyz_lidar,w,l,h,r],一个对象一行 if remove_unknown: # False remove_mask = difficulty == -1 """ gt_boxes_remove = gt_boxes[remove_mask] gt_boxes_remove[:, 3:6] += 0.25 points = prep.remove_points_in_boxes(points, gt_boxes_remove) """ keep_mask = np.logical_not(remove_mask) gt_boxes = gt_boxes[keep_mask] gt_names = gt_names[keep_mask] difficulty = difficulty[keep_mask] if group_ids is not None: # None group_ids = group_ids[keep_mask] gt_boxes_mask = np.array( # 目标类别的对象标签,布尔类型,同样一行一个对象 [n in class_names for n in gt_names], dtype=np.bool_) # 下面用来对去掉DontCare的真值进行采样补充 if db_sampler is not None: # not None # 数据库预处理类里的方法,返回的是该帧数据内各类别用来补充的采样真值数据,包括真值内出现的非目标类别 sampled_dict = db_sampler.sample_all( root_path, gt_boxes, gt_names, num_point_features, random_crop, gt_group_ids=group_ids, # None rect=rect, Trv2c=Trv2c, P2=P2) if sampled_dict is not None: # 下面将原始数据与补充采样数据合并 sampled_gt_names = sampled_dict["gt_names"] sampled_gt_boxes = sampled_dict["gt_boxes"] sampled_points = sampled_dict["points"] sampled_gt_masks = sampled_dict["gt_masks"] # gt_names = gt_names[gt_boxes_mask].tolist() gt_names = np.concatenate([gt_names, sampled_gt_names], axis=0) # gt_names += [s["name"] for s in sampled] gt_boxes = np.concatenate([gt_boxes, sampled_gt_boxes]) gt_boxes_mask = np.concatenate( [gt_boxes_mask, sampled_gt_masks], axis=0) # 真值框是目标类别的标志 if group_ids is not None: # None sampled_group_ids = sampled_dict["group_ids"] group_ids = np.concatenate([group_ids, sampled_group_ids]) if remove_points_after_sample: # False,将采样框所占位置点云去除 points = prep.remove_points_in_boxes( points, sampled_gt_boxes) points = np.concatenate([sampled_points, points], axis=0) # 合并原始点云与采样点云 # unlabeled_mask = np.zeros((gt_boxes.shape[0], ), dtype=np.bool_) if without_reflectivity: # False used_point_axes = list(range(num_point_features)) used_point_axes.pop(3) points = points[:, used_point_axes] pc_range = voxel_generator.point_cloud_range if bev_only: # set z and h to limits, False gt_boxes[:, 2] = pc_range[2] gt_boxes[:, 5] = pc_range[5] - pc_range[2] prep.noise_per_object_v3_( # 每一个对象添加扰动,实际上就是修改每个对象真值框坐标与内部点云坐标 gt_boxes, # 补充过采样数据的真值框 points, # 补充过采样数据的点云 gt_boxes_mask, # 真值框标志(不区分原始数据与采样数据) rotation_perturb=gt_rotation_noise, # 旋转角度范围,平均分布 center_noise_std=gt_loc_noise_std, # 位置正态分布方差 global_random_rot_range=global_random_rot_range, # 全局旋转[0.0,0.0] group_ids=group_ids, # None num_try=100) # should remove unrelated objects after noise per object gt_boxes = gt_boxes[gt_boxes_mask] # 添加扰动后筛选目标类别真值框 gt_names = gt_names[gt_boxes_mask] if group_ids is not None: # Fasle group_ids = group_ids[gt_boxes_mask] gt_classes = np.array( # (gt_num) [class_names.index(n) + 1 for n in gt_names], dtype=np.int32) gt_boxes, points = prep.random_flip(gt_boxes, points) # 随机翻转 gt_boxes, points = prep.global_rotation( # 全局旋转 gt_boxes, points, rotation=global_rotation_noise) gt_boxes, points = prep.global_scaling_v2(gt_boxes, points, # 全局缩放 *global_scaling_noise) # Global translation # 全局定位扰动 gt_boxes, points = prep.global_translate(gt_boxes, points, global_loc_noise_std) bv_range = voxel_generator.point_cloud_range[[0, 1, 3, 4]] mask = prep.filter_gt_box_outside_range(gt_boxes, bv_range) # 过滤超出鸟瞰图范围的真值框 gt_boxes = gt_boxes[mask] gt_classes = gt_classes[mask] if group_ids is not None: # None group_ids = group_ids[mask] # limit rad to [-pi, pi] gt_boxes[:, 6] = box_np_ops.limit_period( # 调整真值转角至目标范围 gt_boxes[:, 6], offset=0.5, period=2 * np.pi) if shuffle_points: # True,打乱全局点云数据 # shuffle is a little slow. np.random.shuffle(points) voxel_size = voxel_generator.voxel_size # [0.16, 0.16, 4] pc_range = voxel_generator.point_cloud_range # [0, -39.68, -3, 69.12, 39.68, 1] grid_size = voxel_generator.grid_size # [432, 496, 1] x,y,z # 生成体素 """ Returns: voxels:[num_voxels, 100, 4] 体素索引映射全局体素特征 coordinates:[num_voxels, 3] 体素索引映射体素坐标 num_points:(num_voxels,) 体素索引映射体素内的点数 """ voxels, coordinates, num_points = voxel_generator.generate( points, max_voxels) example = { 'voxels': voxels, 'num_points': num_points, 'coordinates': coordinates, "num_voxels": np.array([voxels.shape[0]], dtype=np.int64) } example.update({ 'rect': rect, 'Trv2c': Trv2c, 'P2': P2, }) # if not lidar_input: feature_map_size = grid_size[:2] // out_size_factor # [216 248] feature_map_size = [*feature_map_size, 1][::-1] # [1,248,216] if anchor_cache is not None: anchors = anchor_cache["anchors"] anchors_bv = anchor_cache["anchors_bv"] matched_thresholds = anchor_cache["matched_thresholds"] unmatched_thresholds = anchor_cache["unmatched_thresholds"] else: ret = target_assigner.generate_anchors(feature_map_size) anchors = ret["anchors"] anchors = anchors.reshape([-1, 7]) matched_thresholds = ret["matched_thresholds"] unmatched_thresholds = ret["unmatched_thresholds"] anchors_bv = box_np_ops.rbbox2d_to_near_bbox( anchors[:, [0, 1, 3, 4, 6]]) example["anchors"] = anchors # print("debug", anchors.shape, matched_thresholds.shape) # anchors_bv = anchors_bv.reshape([-1, 4]) anchors_mask = None if anchor_area_threshold >= 0: # True coors = coordinates dense_voxel_map = box_np_ops.sparse_sum_for_anchors_mask( # 某处体素是否被采样,否为0,是为1.array[496,432] y,x coors, tuple(grid_size[::-1][1:])) dense_voxel_map = dense_voxel_map.cumsum(0) # 元素值为按列累加到元素的和 dense_voxel_map = dense_voxel_map.cumsum(1) # 元素值为按行累加到元素的和,相当于统计了元素两个维度上之前元素的和 anchors_area = box_np_ops.fused_get_anchors_area( # 统计每个锚框内的体素数量 dense_voxel_map, anchors_bv, voxel_size, pc_range, grid_size) anchors_mask = anchors_area > anchor_area_threshold # 标记超过一个体素的锚框 # example['anchors_mask'] = anchors_mask.astype(np.uint8) example['anchors_mask'] = anchors_mask if generate_bev: # False bev_vxsize = voxel_size.copy() bev_vxsize[:2] /= 2 bev_vxsize[2] *= 2 bev_map = points_to_bev(points, bev_vxsize, pc_range, without_reflectivity) example["bev_map"] = bev_map if not training: return example # 测试数据集不需要创建训练目标 if create_targets: # True targets_dict = target_assigner.assign( anchors, # (248*216*2,7) gt_boxes, # (gt_num, 7) anchors_mask, # (248*216*2,) gt_classes=gt_classes, # (gt_num,) matched_thresholds=matched_thresholds, # (248*216*2,) unmatched_thresholds=unmatched_thresholds) # (248*216*2,) example.update({ 'labels': targets_dict['labels'], # (total_anchors,),所有锚框对应真值类别(1,2...),无对应真值设为0,dontcare设为-1 'reg_targets': targets_dict['bbox_targets'], # (total_anchors, 7),所有锚框对应真值相对锚框的偏差编码,无对应真值设为[0,0,0,0,0,0,0] 'reg_weights': targets_dict['bbox_outside_weights'], # (total_anchors,),所有锚框的外部权重,有对应真值设为1,无对应真值设为0 }) return example
def prep_pointcloud( input_dict, root_path, # voxel_generator, fv_generator, target_assigner, db_sampler=None, max_voxels=20000, class_names=['Car'], remove_outside_points=False, training=True, create_targets=True, shuffle_points=False, reduce_valid_area=False, remove_unknown=False, gt_rotation_noise=[-np.pi / 3, np.pi / 3], gt_loc_noise_std=[1.0, 1.0, 1.0], global_rotation_noise=[-np.pi / 4, np.pi / 4], global_scaling_noise=[0.95, 1.05], global_loc_noise_std=(0.2, 0.2, 0.2), global_random_rot_range=[0.78, 2.35], generate_bev=False, without_reflectivity=False, num_point_features=4, anchor_area_threshold=1, gt_points_drop=0.0, gt_drop_max_keep=10, remove_points_after_sample=False, anchor_cache=None, remove_environment=False, random_crop=False, reference_detections=None, add_rgb_to_points=False, lidar_input=False, unlabeled_db_sampler=None, out_size_factor=2, min_gt_point_dict=None, bev_only=False, use_group_id=False, out_dtype=np.float32, num_classes=1, RGB_embedding=False): """convert point cloud to voxels, create targets if ground truths exists. """ # prep_pointcloud_start = time.time() points = input_dict["points"] # if training: gt_boxes = input_dict["gt_boxes"] gt_names = input_dict["gt_names"] difficulty = input_dict["difficulty"] group_ids = None if use_group_id and "group_ids" in input_dict: group_ids = input_dict["group_ids"] rect = input_dict["rect"] Trv2c = input_dict["Trv2c"] P2 = input_dict["P2"] unlabeled_training = unlabeled_db_sampler is not None image_idx = input_dict["image_idx"] # t1 = time.time() - prep_pointcloud_start if shuffle_points: # shuffle is a little slow. np.random.shuffle(points) # t2 = time.time() - prep_pointcloud_start # print("t2-t1: ", t2-t1) # 0.035 if reference_detections is not None: C, R, T = box_np_ops.projection_matrix_to_CRT_kitti(P2) frustums = box_np_ops.get_frustum_v2(reference_detections, C) frustums -= T # frustums = np.linalg.inv(R) @ frustums.T frustums = np.einsum('ij, akj->aki', np.linalg.inv(R), frustums) frustums = box_np_ops.camera_to_lidar(frustums, rect, Trv2c) surfaces = box_np_ops.corner_to_surfaces_3d_jit(frustums) masks = points_in_convex_polygon_3d_jit(points, surfaces) points = points[masks.any(-1)] if remove_outside_points: # and not lidar_input: image_shape = input_dict["image_shape"] points = box_np_ops.remove_outside_points(points, rect, Trv2c, P2, image_shape) if remove_environment is True: # and training: selected = kitti.keep_arrays_by_name(gt_names, class_names) gt_boxes = gt_boxes[selected] gt_names = gt_names[selected] difficulty = difficulty[selected] if group_ids is not None: group_ids = group_ids[selected] points = prep.remove_points_outside_boxes(points, gt_boxes) # if training: # print(gt_names) selected = kitti.drop_arrays_by_name(gt_names, ["DontCare"]) gt_boxes = gt_boxes[selected] gt_names = gt_names[selected] difficulty = difficulty[selected] if group_ids is not None: group_ids = group_ids[selected] # t3 = time.time() - prep_pointcloud_start # print("t3-t2: ", t3 - t2) # 0.0002 gt_boxes = box_np_ops.box_camera_to_lidar(gt_boxes, rect, Trv2c) if remove_unknown: remove_mask = difficulty == -1 """ gt_boxes_remove = gt_boxes[remove_mask] gt_boxes_remove[:, 3:6] += 0.25 points = prep.remove_points_in_boxes(points, gt_boxes_remove) """ keep_mask = np.logical_not(remove_mask) gt_boxes = gt_boxes[keep_mask] gt_names = gt_names[keep_mask] difficulty = difficulty[keep_mask] if group_ids is not None: group_ids = group_ids[keep_mask] gt_boxes_mask = np.array([n in class_names for n in gt_names], dtype=np.bool_) # t4 = time.time() - prep_pointcloud_start # print("t4-t3: ", t4 - t3) # 0.001 if RGB_embedding: RGB_image = cv2.imread(input_dict['image_path']) points_camera = box_np_ops.box_lidar_to_camera(points[:, :3], rect, Trv2c) points_to_image_idx = box_np_ops.project_to_image(points_camera, P2) points_to_image_idx = points_to_image_idx.astype(int) mask = box_np_ops.remove_points_outside_image(RGB_image, points_to_image_idx) points = points[mask] points_to_image_idx = points_to_image_idx[mask] BGR = RGB_image[points_to_image_idx[:, 1], points_to_image_idx[:, 0]] points = np.concatenate((points, BGR), axis=1) # test_mask = points_camera[mask][:, 0] < 0 # test_image_idx = points_to_image_idx[test_mask] # RGB_image[test_image_idx[:, 1], test_image_idx[:, 0]] = [255, 0, 0] # test_mask = points_camera[mask][:, 0] >= 0 # test_image_idx = points_to_image_idx[test_mask] # RGB_image[test_image_idx[:, 1], test_image_idx[:, 0]] = [0, 0, 255] # print() # t5 = time.time() - prep_pointcloud_start # print("t5-t4: ", t5 - t4) # 0.019 # TODO if db_sampler is not None and training: # and not RGB_embedding: if RGB_embedding: num_point_features += 3 fg_points_mask = box_np_ops.points_in_rbbox(points, gt_boxes) fg_points_list = [] bg_points_mask = np.zeros((points.shape[0]), dtype=bool) for i in range(fg_points_mask.shape[1]): fg_points_list.append(points[fg_points_mask[:, i]]) bg_points_mask = np.logical_or(bg_points_mask, fg_points_mask[:, i]) bg_points_mask = np.logical_not(bg_points_mask) sampled_dict = db_sampler.sample_all(root_path, points[bg_points_mask], gt_boxes, gt_names, fg_points_list, num_point_features, random_crop, gt_group_ids=group_ids, rect=rect, Trv2c=Trv2c, P2=P2) # sampled_dict = db_sampler.sample_all( # root_path, # gt_boxes, # gt_names, # num_point_features, # random_crop, # gt_group_ids=group_ids, # rect=rect, # Trv2c=Trv2c, # P2=P2) # t_sample_all = time.time() - prep_pointcloud_start # print("t_sample_all - t5: ", t_sample_all - t5) # 3.83 if sampled_dict is not None: sampled_gt_names = sampled_dict["gt_names"] sampled_gt_boxes = sampled_dict["gt_boxes"] points = sampled_dict["points"] sampled_gt_masks = sampled_dict["gt_masks"] remained_boxes_idx = sampled_dict["remained_boxes_idx"] # gt_names = gt_names[gt_boxes_mask].tolist() gt_names = np.concatenate([gt_names, sampled_gt_names], axis=0) # gt_names += [s["name"] for s in sampled] gt_boxes = np.concatenate([gt_boxes, sampled_gt_boxes]) gt_boxes_mask = np.concatenate([gt_boxes_mask, sampled_gt_masks], axis=0) gt_names = gt_names[remained_boxes_idx] gt_boxes = gt_boxes[remained_boxes_idx] gt_boxes_mask = gt_boxes_mask[remained_boxes_idx] if group_ids is not None: sampled_group_ids = sampled_dict["group_ids"] group_ids = np.concatenate([group_ids, sampled_group_ids]) group_ids = group_ids[remained_boxes_idx] # if remove_points_after_sample: # # points = prep.remove_points_in_boxes( # # points, sampled_gt_boxes) # locs = sampled_gt_boxes[:, 0:3] # dims = sampled_gt_boxes[:, 3:6] # angles = sampled_gt_boxes[:, 6] # camera_box_origin = [0.5, 0.5, 0] # # box_corners = box_np_ops.center_to_corner_box3d( # locs, dims, angles, camera_box_origin, axis=2) # box_corners_in_image = box_np_ops.project_to_fv_image( # box_corners, example['grid_size'][i], example['meta'][i]) # box_centers_in_image = box_np_ops.project_to_fv_image( # locs, example['grid_size'][i], example['meta'][i]) # t_sample_all2 = time.time() - prep_pointcloud_start # print("t_sample_all2 - t_sample_all: ", t_sample_all2 - t_sample_all) # 0.0002 # unlabeled_mask = np.zeros((gt_boxes.shape[0], ), dtype=np.bool_) # if without_reflectivity and training: # used_point_axes = list(range(num_point_features)) # used_point_axes.pop(3) # points = points[:, used_point_axes] # pc_range = voxel_generator.point_cloud_range # bev_only = False # if bev_only: # set z and h to limits # gt_boxes[:, 2] = pc_range[2] # gt_boxes[:, 5] = pc_range[5] - pc_range[2] if training: gt_loc_noise_std = [0.0, 0.0, 0.0] prep.noise_per_object_v3_( gt_boxes, points, gt_boxes_mask, rotation_perturb=gt_rotation_noise, center_noise_std=gt_loc_noise_std, global_random_rot_range=global_random_rot_range, group_ids=group_ids, num_try=100) # t_noise = time.time() - prep_pointcloud_start # print("t_noise - t_sample_all2: ", t_noise - t_sample_all2) # 12.01 # should remove unrelated objects after noise per object gt_boxes = gt_boxes[gt_boxes_mask] gt_names = gt_names[gt_boxes_mask] if group_ids is not None: group_ids = group_ids[gt_boxes_mask] gt_classes = np.array([class_names.index(n) + 1 for n in gt_names], dtype=np.int32) # t6 = time.time() - prep_pointcloud_start # print("t6-t5: ", t6 - t5) # 16.0 if training: gt_boxes, points = prep.random_flip(gt_boxes, points) # gt_boxes, points = prep.global_rotation( # gt_boxes, points, rotation=global_rotation_noise) gt_boxes, points = prep.global_scaling_v2(gt_boxes, points, *global_scaling_noise) # Global translation # gt_boxes, points = prep.global_translate(gt_boxes, points, global_loc_noise_std) # bv_range = voxel_generator.point_cloud_range[[0, 1, 3, 4]] bv_range = [0, -40, 70.4, 40] mask = prep.filter_gt_box_outside_range(gt_boxes, bv_range) gt_boxes = gt_boxes[mask] gt_classes = gt_classes[mask] if group_ids is not None: group_ids = group_ids[mask] # limit rad to [-pi, pi] gt_boxes[:, 6] = box_np_ops.limit_period(gt_boxes[:, 6], offset=0.5, period=2 * np.pi) # TODO # if shuffle_points: # # shuffle is a little slow. # np.random.shuffle(points) # # t7 = time.time() - prep_pointcloud_start # # print("t7-t6: ", t7 - t6) # 1.95 # voxels, coordinates, num_points = voxel_generator.generate( # points, max_voxels, RGB_embedding=RGB_embedding) # # t8 = time.time() - prep_pointcloud_start # # print("t8-t7: ", t8 - t7) # 2.0 # voxel_size = voxel_generator.voxel_size # grid_size = voxel_generator.grid_size # pc_range = copy.deepcopy(voxel_generator.point_cloud_range) # grid_size = voxel_generator.grid_size # phi_min = voxel_generator.phi_min # theta_min = voxel_generator.theta_min # image_h, image_w = grid_size[1], grid_size[0] # c = np.array([image_w / 2., image_h / 2.]) # s = np.array([image_w, image_h], dtype=np.int32) # meta = {'c': c, 's': s, 'calib': P2, 'phi_min': phi_min, 'theta_min': theta_min} # t7 = time.time() - prep_pointcloud_start # print("t7-t6: ", t7 - t6) # 1.95 fv_image, points_mask = fv_generator.generate(points, RGB_embedding=RGB_embedding, occupancy_embedding=False) # t8 = time.time() - prep_pointcloud_start # print("t8-t7: ", t8 - t7) # 2.0 fv_dim = fv_generator.fv_dim pc_range = copy.deepcopy(fv_generator.spherical_coord_range) grid_size = fv_generator.grid_size phi_min = fv_generator.phi_min theta_min = fv_generator.theta_min image_h, image_w = fv_dim[1], fv_dim[0] c = np.array([image_w / 2., image_h / 2.]) s = np.array([image_w, image_h], dtype=np.int32) meta = { 'c': c, 's': s, 'calib': P2, 'phi_min': phi_min, 'theta_min': theta_min } fv_image = np.transpose(fv_image, [2, 1, 0]) max_objs = 50 num_objs = min(gt_boxes.shape[0], max_objs) box_np_ops.change_box3d_center_(gt_boxes, src=[0.5, 0.5, 0], dst=[0.5, 0.5, 0.5]) spherical_gt_boxes = np.zeros((max_objs, gt_boxes.shape[1])) spherical_gt_boxes[:num_objs, :] = gt_boxes[:num_objs, :] spherical_gt_boxes[:num_objs, :] = convert_to_spherical_coor( gt_boxes[:num_objs, :]) spherical_gt_boxes[:num_objs, 0] -= phi_min spherical_gt_boxes[:num_objs, 1] -= theta_min spherical_gt_boxes[:num_objs, 0] /= grid_size[0] spherical_gt_boxes[:num_objs, 1] /= grid_size[1] spherical_gt_boxes, num_objs = filter_outside_range( spherical_gt_boxes, num_objs, fv_dim) # t9 = time.time() - prep_pointcloud_start # print("t9-t8: ", t9 - t8) # 0.0005 example = { 'fv_image': fv_image, 'grid_size': grid_size, 'pc_range': pc_range, 'meta': meta, 'spherical_gt_boxes': spherical_gt_boxes, 'resized_image_shape': grid_size } example.update({'rect': rect, 'Trv2c': Trv2c, 'P2': P2}) if RGB_embedding: RGB_image = cv2.resize(RGB_image, (image_w, image_h)) example.update({'RGB_image': RGB_image}) if training: hm = np.zeros((num_classes, image_h, image_w), dtype=np.float32) reg = np.zeros((max_objs, 2), dtype=np.float32) dep = np.zeros((max_objs, 1), dtype=np.float32) rotbin = np.zeros((max_objs, 2), dtype=np.int64) rotres = np.zeros((max_objs, 2), dtype=np.float32) dim = np.zeros((max_objs, 3), dtype=np.float32) ind = np.zeros((max_objs), dtype=np.int64) reg_mask = np.zeros((max_objs), dtype=np.uint8) rot_mask = np.zeros((max_objs), dtype=np.uint8) # # hm = np.zeros((num_classes, image_h, image_w), dtype=np.float32) # reg = np.zeros((image_w, image_h, 2), dtype=np.float32) # dep = np.zeros((image_w, image_h, 1), dtype=np.float32) # rotbin = np.zeros((image_w, image_h, 2), dtype=np.int64) # rotres = np.zeros((image_w, image_h, 2), dtype=np.float32) # dim = np.zeros((image_w, image_h, 3), dtype=np.float32) # # ind = np.zeros((max_objs), dtype=np.int64) # fg_mask = np.zeros((image_w, image_h), dtype=np.uint8) # # rot_mask = np.zeros((max_objs), dtype=np.uint8) draw_gaussian = draw_umich_gaussian # center heatmap radius = int(image_h / 30) # radius = int(image_h / 25) for k in range(num_objs): gt_3d_box = spherical_gt_boxes[k] cls_id = 0 # print('heatmap gaussian radius: ' + str(radius)) ct = np.array([gt_3d_box[0], gt_3d_box[1]], dtype=np.float32) ct_int = ct.astype(np.int32) draw_gaussian(hm[cls_id], ct, radius) # depth(distance), wlh dep[k] = gt_3d_box[2] dim[k] = gt_3d_box[3:6] # dep[ct_int[0], ct_int[1], 0] = gt_3d_box[2] # dim[ct_int[0], ct_int[1], :] = gt_3d_box[3:6] # reg, ind, mask reg[k] = ct - ct_int ind[k] = ct_int[1] * image_w + ct_int[0] reg_mask[k] = rot_mask[k] = 1 # fg_mask[ct_int[0], ct_int[1]] = 1 # ry ry = gt_3d_box[6] if ry < np.pi / 6. or ry > 5 * np.pi / 6.: rotbin[k, 0] = 1 rotres[k, 0] = ry - (-0.5 * np.pi) # rotbin[ct_int[0], ct_int[1], 0] = 1 # rotres[ct_int[0], ct_int[1], 0] = ry - (-0.5 * np.pi) if ry > -np.pi / 6. or ry < -5 * np.pi / 6.: rotbin[k, 1] = 1 rotres[k, 1] = ry - (0.5 * np.pi) # rotbin[ct_int[0], ct_int[1], 1] = 1 # rotres[ct_int[0], ct_int[1], 1] = ry - (0.5 * np.pi) example.update({ 'hm': hm, 'dep': dep, 'dim': dim, 'ind': ind, 'rotbin': rotbin, 'rotres': rotres, 'reg_mask': reg_mask, 'rot_mask': rot_mask, 'reg': reg }) # example.update({ # 'hm': hm, 'dep': dep, 'dim': dim, # 'rotbin': rotbin, 'rotres': rotres, # 'fg_mask': fg_mask, 'reg': reg # }) # t10 = time.time() - prep_pointcloud_start # print("total: ", t10) # 19.58 return example
def prep_pointcloud(input_dict, root_path, voxel_generator, target_assigner, db_sampler=None, max_voxels=20000, class_names=['Car', "Cyclist", "Pedestrian"], remove_outside_points=False, training=True, create_targets=True, shuffle_points=False, reduce_valid_area=False, remove_unknown=False, gt_rotation_noise=[-np.pi / 3, np.pi / 3], gt_loc_noise_std=[1.0, 1.0, 1.0], global_rotation_noise=[-np.pi / 4, np.pi / 4], global_scaling_noise=[0.95, 1.05], global_loc_noise_std=(0.2, 0.2, 0.2), global_random_rot_range=[0.78, 2.35], generate_bev=False, without_reflectivity=False, num_point_features=4, anchor_area_threshold=1, gt_points_drop=0.0, gt_drop_max_keep=10, remove_points_after_sample=True, anchor_cache=None, remove_environment=False, random_crop=False, reference_detections=None, add_rgb_to_points=False, lidar_input=False, unlabeled_db_sampler=None, out_size_factor=2, min_gt_point_dict=None, bev_only=False, use_group_id=False, out_dtype=np.float32, max_objs=300, length=248, width=216): """convert point cloud to voxels, create targets if ground truths exists. """ points = input_dict["points"] pc_range = voxel_generator.point_cloud_range hist, bin_edges = np.histogram(points[:, 2], bins=10, range=(pc_range[2], pc_range[5])) idx = np.argmax(hist) ground = (bin_edges[idx] + bin_edges[idx + 1]) / 2 if training: gt_boxes = input_dict["gt_boxes"] gt_names = input_dict["gt_names"] difficulty = input_dict["difficulty"] group_ids = None if use_group_id and "group_ids" in input_dict: group_ids = input_dict["group_ids"] rect = input_dict["rect"] Trv2c = input_dict["Trv2c"] P2 = input_dict["P2"] unlabeled_training = unlabeled_db_sampler is not None image_idx = input_dict["image_idx"] if reference_detections is not None: C, R, T = box_np_ops.projection_matrix_to_CRT_kitti(P2) frustums = box_np_ops.get_frustum_v2(reference_detections, C) frustums -= T # frustums = np.linalg.inv(R) @ frustums.T frustums = np.einsum('ij, akj->aki', np.linalg.inv(R), frustums) frustums = box_np_ops.camera_to_lidar(frustums, rect, Trv2c) surfaces = box_np_ops.corner_to_surfaces_3d_jit(frustums) masks = points_in_convex_polygon_3d_jit(points, surfaces) points = points[masks.any(-1)] if remove_outside_points and not lidar_input: image_shape = input_dict["image_shape"] points = box_np_ops.remove_outside_points(points, rect, Trv2c, P2, image_shape) if remove_environment is True and training: selected = kitti.keep_arrays_by_name(gt_names, class_names) gt_boxes = gt_boxes[selected] gt_names = gt_names[selected] difficulty = difficulty[selected] if group_ids is not None: group_ids = group_ids[selected] points = prep.remove_points_outside_boxes(points, gt_boxes) if training: # print(gt_names) selected = kitti.drop_arrays_by_name(gt_names, ["DontCare"]) gt_boxes = gt_boxes[selected] gt_names = gt_names[selected] difficulty = difficulty[selected] if group_ids is not None: group_ids = group_ids[selected] gt_boxes = box_np_ops.box_camera_to_lidar(gt_boxes, rect, Trv2c) if remove_unknown: remove_mask = difficulty == -1 """ gt_boxes_remove = gt_boxes[remove_mask] gt_boxes_remove[:, 3:6] += 0.25 points = prep.remove_points_in_boxes(points, gt_boxes_remove) """ keep_mask = np.logical_not(remove_mask) gt_boxes = gt_boxes[keep_mask] gt_names = gt_names[keep_mask] difficulty = difficulty[keep_mask] if group_ids is not None: group_ids = group_ids[keep_mask] gt_boxes_mask = np.array([n in class_names for n in gt_names], dtype=np.bool_) if db_sampler is not None: sampled_dict = db_sampler.sample_all(root_path, gt_boxes, gt_names, num_point_features, random_crop, gt_group_ids=group_ids, rect=rect, Trv2c=Trv2c, P2=P2) if sampled_dict is not None: sampled_gt_names = sampled_dict["gt_names"] sampled_gt_boxes = sampled_dict["gt_boxes"] sampled_points = sampled_dict["points"] sampled_gt_masks = sampled_dict["gt_masks"] # gt_names = gt_names[gt_boxes_mask].tolist() gt_names = np.concatenate([gt_names, sampled_gt_names], axis=0) # gt_names += [s["name"] for s in sampled] gt_boxes = np.concatenate([gt_boxes, sampled_gt_boxes]) gt_boxes_mask = np.concatenate( [gt_boxes_mask, sampled_gt_masks], axis=0) if group_ids is not None: sampled_group_ids = sampled_dict["group_ids"] group_ids = np.concatenate([group_ids, sampled_group_ids]) if remove_points_after_sample: points = prep.remove_points_in_boxes( points, sampled_gt_boxes) points = np.concatenate([sampled_points, points], axis=0) # unlabeled_mask = np.zeros((gt_boxes.shape[0], ), dtype=np.bool_) if without_reflectivity: used_point_axes = list(range(num_point_features)) used_point_axes.pop(3) points = points[:, used_point_axes] if bev_only: # set z and h to limits gt_boxes[:, 2] = pc_range[2] gt_boxes[:, 5] = pc_range[5] - pc_range[2] prep.noise_per_object_v3_( gt_boxes, points, gt_boxes_mask, rotation_perturb=gt_rotation_noise, center_noise_std=gt_loc_noise_std, global_random_rot_range=global_random_rot_range, group_ids=group_ids, num_try=100) # should remove unrelated objects after noise per object gt_boxes = gt_boxes[gt_boxes_mask] gt_names = gt_names[gt_boxes_mask] if group_ids is not None: group_ids = group_ids[gt_boxes_mask] gt_classes = np.array([class_names.index(n) + 1 for n in gt_names], dtype=np.int32) gt_boxes, points = prep.random_flip(gt_boxes, points) gt_boxes, points = prep.global_rotation(gt_boxes, points, rotation=global_rotation_noise) gt_boxes, points = prep.global_scaling_v2(gt_boxes, points, *global_scaling_noise) # Global translation gt_boxes, points = prep.global_translate(gt_boxes, points, global_loc_noise_std) bv_range = voxel_generator.point_cloud_range[[0, 1, 3, 4]] mask = prep.filter_gt_box_outside_range(gt_boxes, bv_range) gt_boxes = gt_boxes[mask] gt_classes = gt_classes[mask] if group_ids is not None: group_ids = group_ids[mask] # limit rad to [-pi, pi] gt_boxes[:, 6] = box_np_ops.limit_period(gt_boxes[:, 6], offset=0.5, period=2 * np.pi) if shuffle_points: # shuffle is a little slow. np.random.shuffle(points) voxel_size = voxel_generator.voxel_size pc_range = voxel_generator.point_cloud_range grid_size = voxel_generator.grid_size voxels, coordinates, num_points = voxel_generator.generate( points, max_voxels) example = { 'voxels': voxels, 'num_points': num_points, 'coordinates': coordinates, "num_voxels": np.array([voxels.shape[0]], dtype=np.int64), "ground": ground } example.update({ 'rect': rect, 'Trv2c': Trv2c, 'P2': P2, }) if generate_bev: bev_vxsize = voxel_size.copy() bev_vxsize[:2] /= 2 bev_vxsize[2] *= 2 bev_map = points_to_bev(points, bev_vxsize, pc_range, without_reflectivity) example["bev_map"] = bev_map #============================ NEW CODE =================================== if training: num_classes = len(class_names) hm = np.zeros((num_classes, length, width), dtype=np.float32) # wh = np.zeros((max_objs, 2), dtype=np.float32) reg = np.zeros((max_objs, 2), dtype=np.float32) rotbin = np.zeros((max_objs, 2), dtype=np.int64) rotres = np.zeros((max_objs, 2), dtype=np.float32) dim = np.zeros((max_objs, 3), dtype=np.float32) ind = np.zeros((max_objs), dtype=np.int64) reg_mask = np.zeros((max_objs), dtype=np.uint8) rot_mask = np.zeros((max_objs), dtype=np.uint8) num_objs = min(len(gt_boxes), max_objs) draw_gaussian = draw_msra_gaussian # if self.opt.mse_loss else draw_umich_gaussian gt_det = [] xmin, ymin, _, xmax, ymax, _ = pc_range for k in range(num_objs): box = gt_boxes[k] box[0] = np.clip(box[0], xmin, xmax) box[1] = np.clip(box[1], ymin, ymax) alpha = box[6] - np.arctan2(-box[1], box[0]) cls_id = gt_classes[k] - 1 cx = (box[0] - xmin) * (width - 1) / (xmax - xmin) cy = (box[1] - ymin) * (length - 1) / (ymax - ymin) lx = box[4] * (width - 1) / (xmax - xmin) ly = box[3] * (length - 1) / (ymax - ymin) if lx > 0 and ly > 0: radius = gaussian_radius((ly, lx)) radius = max(0, int(radius)) ct = np.array([cx, cy], dtype=np.float32) ct_int = ct.astype(np.int32) if cls_id < 0: ignore_id = [_ for _ in range(num_classes)] \ if cls_id == - 1 else [- cls_id - 2] for cc in ignore_id: draw_gaussian(hm[cc], ct, radius) hm[ignore_id, ct_int[1], ct_int[0]] = 0.9999 continue draw_gaussian(hm[cls_id], ct, radius) if alpha < np.pi / 6. or alpha > 5 * np.pi / 6.: rotbin[k, 0] = 1 rotres[k, 0] = alpha - (-0.5 * np.pi) if alpha > -np.pi / 6. or alpha < -5 * np.pi / 6.: rotbin[k, 1] = 1 rotres[k, 1] = alpha - (0.5 * np.pi) dim[k] = box[3:6] #w,l,h ind[k] = ct_int[1] * width + ct_int[0] reg[k] = ct - ct_int reg_mask[k] = 1 #if not training else 0 rot_mask[k] = 1 example.update({ 'hm': hm, 'dim': dim, 'ind': ind, 'rotbin': rotbin, 'rotres': rotres, 'reg_mask': reg_mask, 'rot_mask': rot_mask, 'reg': reg }) #============================ NEW CODE =================================== return example
def prep_pointcloud(input_dict, root_path, voxel_generator, target_assigner, db_sampler=None, max_voxels=70000, class_names=['Car'], remove_outside_points=False, training=True, create_targets=True, shuffle_points=False, reduce_valid_area=False, remove_unknown=False, gt_rotation_noise=[-np.pi / 3, np.pi / 3], gt_loc_noise_std=[1.0, 1.0, 1.0], global_rotation_noise=[-np.pi / 4, np.pi / 4], global_scaling_noise=[0.95, 1.05], global_loc_noise_std=(0.2, 0.2, 0.2), global_random_rot_range=[0.78, 2.35], generate_bev=False, without_reflectivity=False, num_point_features=4, anchor_area_threshold=1, gt_points_drop=0.0, gt_drop_max_keep=10, remove_points_after_sample=True, anchor_cache=None, remove_environment=False, random_crop=False, reference_detections=None, add_rgb_to_points=False, lidar_input=False, unlabeled_db_sampler=None, out_size_factor=2, min_gt_point_dict=None, bev_only=False, use_group_id=False, out_dtype=np.float32): """convert point cloud to voxels, create targets if ground truths exists. """ points = input_dict["lidar"]["points"] if training: gt_boxes = input_dict['lidar']['annotations']["gt_boxes"] gt_names = input_dict['lidar']['annotations']["gt_names"] # difficulty = input_dict["difficulty"] group_ids = None if use_group_id and "group_ids" in input_dict: group_ids = input_dict["group_ids"] # rect = input_dict["rect"] # Trv2c = input_dict["Trv2c"] # P2 = input_dict["P2"] unlabeled_training = unlabeled_db_sampler is not None calib = None # print(gt_dict) # print("+++++++++++++++1111111+++++++++++++++") if "calib" in input_dict: calib = input_dict["calib"] if remove_environment is True and training: selected = kitti.keep_arrays_by_name(gt_names, class_names) gt_boxes = gt_boxes[selected] gt_names = gt_names[selected] # difficulty = difficulty[selected] if group_ids is not None: group_ids = group_ids[selected] points = prep.remove_points_outside_boxes(points, gt_boxes) if training: # print(gt_names) selected = kitti.drop_arrays_by_name(gt_names, ["DontCare"]) gt_boxes = gt_boxes[selected] gt_names = gt_names[selected] # difficulty = difficulty[selected] if group_ids is not None: group_ids = group_ids[selected] # if remove_unknown: # remove_mask = difficulty == -1 # """ # gt_boxes_remove = gt_boxes[remove_mask] # gt_boxes_remove[:, 3:6] += 0.25 # points = prep.remove_points_in_boxes(points, gt_boxes_remove) # """ # keep_mask = np.logical_not(remove_mask) # gt_boxes = gt_boxes[keep_mask] # gt_names = gt_names[keep_mask] # difficulty = difficulty[keep_mask] # if group_ids is not None: # group_ids = group_ids[keep_mask] gt_boxes_mask = np.array( [n in class_names for n in gt_names], dtype=np.bool_) if db_sampler is not None: sampled_dict = db_sampler.sample_all( root_path, gt_boxes, gt_names, num_point_features, random_crop, gt_group_ids=group_ids ) if sampled_dict is not None: sampled_gt_names = sampled_dict["gt_names"] sampled_gt_boxes = sampled_dict["gt_boxes"] sampled_points = sampled_dict["points"] sampled_gt_masks = sampled_dict["gt_masks"] # gt_names = gt_names[gt_boxes_mask].tolist() gt_names = np.concatenate([gt_names, sampled_gt_names], axis=0) # gt_names += [s["name"] for s in sampled] gt_boxes = np.concatenate([gt_boxes, sampled_gt_boxes]) gt_boxes_mask = np.concatenate( [gt_boxes_mask, sampled_gt_masks], axis=0) if group_ids is not None: sampled_group_ids = sampled_dict["group_ids"] group_ids = np.concatenate([group_ids, sampled_group_ids]) if remove_points_after_sample: points = prep.remove_points_in_boxes( points, sampled_gt_boxes) points = np.concatenate([sampled_points, points], axis=0) # unlabeled_mask = np.zeros((gt_boxes.shape[0], ), dtype=np.bool_) if without_reflectivity: used_point_axes = list(range(num_point_features)) used_point_axes.pop(3) points = points[:, used_point_axes] pc_range = voxel_generator.point_cloud_range if bev_only: # set z and h to limits gt_boxes[:, 2] = pc_range[2] gt_boxes[:, 5] = pc_range[5] - pc_range[2] prep.noise_per_object_v3_( gt_boxes, points, gt_boxes_mask, rotation_perturb=gt_rotation_noise, center_noise_std=gt_loc_noise_std, global_random_rot_range=global_random_rot_range, group_ids=group_ids, num_try=100) # should remove unrelated objects after noise per object gt_boxes = gt_boxes[gt_boxes_mask] gt_names = gt_names[gt_boxes_mask] if group_ids is not None: group_ids = group_ids[gt_boxes_mask] gt_classes = np.array( [class_names.index(n) + 1 for n in gt_names], dtype=np.int32) gt_boxes, points = prep.random_flip(gt_boxes, points) gt_boxes, points = prep.global_rotation( gt_boxes, points, rotation=global_rotation_noise) gt_boxes, points = prep.global_scaling_v2(gt_boxes, points, *global_scaling_noise) # Global translation gt_boxes, points = prep.global_translate(gt_boxes, points, global_loc_noise_std) bv_range = voxel_generator.point_cloud_range[[0, 1, 3, 4]] mask = prep.filter_gt_box_outside_range(gt_boxes, bv_range) gt_boxes = gt_boxes[mask] gt_classes = gt_classes[mask] if group_ids is not None: group_ids = group_ids[mask] # limit rad to [-pi, pi] gt_boxes[:, 6] = box_np_ops.limit_period( gt_boxes[:, 6], offset=0.5, period=2 * np.pi) if shuffle_points: # shuffle is a little slow. np.random.shuffle(points) # [0, -40, -3, 70.4, 40, 1] voxel_size = voxel_generator.voxel_size pc_range = voxel_generator.point_cloud_range grid_size = voxel_generator.grid_size # [352, 400] # max_voxels: maximum number of voxels voxels, coordinates, num_points = voxel_generator.generate( points, max_voxels) example = { 'voxels': voxels, 'num_points': num_points, 'coordinates': coordinates, "num_voxels": np.array([voxels.shape[0]], dtype=np.int64), } # if not lidar_input: feature_map_size = grid_size[:2] // out_size_factor feature_map_size = [*feature_map_size, 1][::-1] if anchor_cache is not None: anchors = anchor_cache["anchors"] anchors_bv = anchor_cache["anchors_bv"] matched_thresholds = anchor_cache["matched_thresholds"] unmatched_thresholds = anchor_cache["unmatched_thresholds"] else: ret = target_assigner.generate_anchors(feature_map_size) anchors = ret["anchors"] anchors = anchors.reshape([-1, 7]) matched_thresholds = ret["matched_thresholds"] unmatched_thresholds = ret["unmatched_thresholds"] anchors_bv = box_np_ops.rbbox2d_to_near_bbox( anchors[:, [0, 1, 3, 4, 6]]) example["anchors"] = anchors # print("debug", anchors.shape, matched_thresholds.shape) # anchors_bv = anchors_bv.reshape([-1, 4]) anchors_mask = None if anchor_area_threshold >= 0: coors = coordinates dense_voxel_map = box_np_ops.sparse_sum_for_anchors_mask( coors, tuple(grid_size[::-1][1:])) dense_voxel_map = dense_voxel_map.cumsum(0) dense_voxel_map = dense_voxel_map.cumsum(1) anchors_area = box_np_ops.fused_get_anchors_area( dense_voxel_map, anchors_bv, voxel_size, pc_range, grid_size) anchors_mask = anchors_area > anchor_area_threshold # example['anchors_mask'] = anchors_mask.astype(np.uint8) example['anchors_mask'] = anchors_mask if generate_bev: bev_vxsize = voxel_size.copy() bev_vxsize[:2] /= 2 bev_vxsize[2] *= 2 bev_map = points_to_bev(points, bev_vxsize, pc_range, without_reflectivity) example["bev_map"] = bev_map if not training: return example if create_targets: targets_dict = target_assigner.assign( anchors, gt_boxes, anchors_mask, gt_classes=gt_classes, matched_thresholds=matched_thresholds, unmatched_thresholds=unmatched_thresholds) example.update({ 'labels': targets_dict['labels'], 'reg_targets': targets_dict['bbox_targets'], 'reg_weights': targets_dict['bbox_outside_weights'], }) example["points"]= input_dict["lidar"]["points"] example['gt_boxes'] = input_dict['lidar']['annotations']["gt_boxes"] example['gt_names'] = input_dict['lidar']['annotations']["gt_names"] return example