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center_head.py
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center_head.py
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import copy
import numpy as np
import torch
import torch.nn as nn
from torch.nn.init import kaiming_normal_
from ..model_utils import model_nms_utils
from ..model_utils import centernet_utils
from ...utils import loss_utils
class SeparateHead(nn.Module):
def __init__(self, input_channels, sep_head_dict, init_bias=-2.19, use_bias=False):
super().__init__()
self.sep_head_dict = sep_head_dict
for cur_name in self.sep_head_dict:
output_channels = self.sep_head_dict[cur_name]['out_channels']
num_conv = self.sep_head_dict[cur_name]['num_conv']
fc_list = []
for k in range(num_conv - 1):
fc_list.append(nn.Sequential(
nn.Conv2d(input_channels, input_channels, kernel_size=3, stride=1, padding=1, bias=use_bias),
nn.BatchNorm2d(input_channels),
nn.ReLU()
))
fc_list.append(nn.Conv2d(input_channels, output_channels, kernel_size=3, stride=1, padding=1, bias=True))
fc = nn.Sequential(*fc_list)
if 'hm' in cur_name:
fc[-1].bias.data.fill_(init_bias)
else:
for m in fc.modules():
if isinstance(m, nn.Conv2d):
kaiming_normal_(m.weight.data)
if hasattr(m, "bias") and m.bias is not None:
nn.init.constant_(m.bias, 0)
self.__setattr__(cur_name, fc)
def forward(self, x):
ret_dict = {}
for cur_name in self.sep_head_dict:
ret_dict[cur_name] = self.__getattr__(cur_name)(x)
return ret_dict
class CenterHead(nn.Module):
def __init__(self, model_cfg, input_channels, num_class, class_names, grid_size, point_cloud_range, voxel_size,
predict_boxes_when_training=True):
super().__init__()
self.model_cfg = model_cfg
self.num_class = num_class
self.grid_size = grid_size
self.point_cloud_range = point_cloud_range
self.voxel_size = voxel_size
self.feature_map_stride = self.model_cfg.TARGET_ASSIGNER_CONFIG.get('FEATURE_MAP_STRIDE', None)
self.class_names = class_names
self.class_names_each_head = []
self.class_id_mapping_each_head = []
for cur_class_names in self.model_cfg.CLASS_NAMES_EACH_HEAD:
self.class_names_each_head.append([x for x in cur_class_names if x in class_names])
cur_class_id_mapping = torch.from_numpy(np.array(
[self.class_names.index(x) for x in cur_class_names if x in class_names]
)).cuda()
self.class_id_mapping_each_head.append(cur_class_id_mapping)
total_classes = sum([len(x) for x in self.class_names_each_head])
assert total_classes == len(self.class_names), f'class_names_each_head={self.class_names_each_head}'
self.shared_conv = nn.Sequential(
nn.Conv2d(
input_channels, self.model_cfg.SHARED_CONV_CHANNEL, 3, stride=1, padding=1,
bias=self.model_cfg.get('USE_BIAS_BEFORE_NORM', False)
),
nn.BatchNorm2d(self.model_cfg.SHARED_CONV_CHANNEL),
nn.ReLU(),
)
self.heads_list = nn.ModuleList()
self.separate_head_cfg = self.model_cfg.SEPARATE_HEAD_CFG
for idx, cur_class_names in enumerate(self.class_names_each_head):
cur_head_dict = copy.deepcopy(self.separate_head_cfg.HEAD_DICT)
cur_head_dict['hm'] = dict(out_channels=len(cur_class_names), num_conv=self.model_cfg.NUM_HM_CONV)
self.heads_list.append(
SeparateHead(
input_channels=self.model_cfg.SHARED_CONV_CHANNEL,
sep_head_dict=cur_head_dict,
init_bias=-2.19,
use_bias=self.model_cfg.get('USE_BIAS_BEFORE_NORM', False)
)
)
self.predict_boxes_when_training = predict_boxes_when_training
self.forward_ret_dict = {}
self.build_losses()
def build_losses(self):
self.add_module('hm_loss_func', loss_utils.FocalLossCenterNet())
self.add_module('reg_loss_func', loss_utils.RegLossCenterNet())
def assign_target_of_single_head(
self, num_classes, gt_boxes, feature_map_size, feature_map_stride, num_max_objs=500,
gaussian_overlap=0.1, min_radius=2
):
"""
Args:
gt_boxes: (N, 8)
feature_map_size: (2), [x, y]
Returns:
"""
heatmap = gt_boxes.new_zeros(num_classes, feature_map_size[1], feature_map_size[0])
ret_boxes = gt_boxes.new_zeros((num_max_objs, gt_boxes.shape[-1] - 1 + 1))
inds = gt_boxes.new_zeros(num_max_objs).long()
mask = gt_boxes.new_zeros(num_max_objs).long()
x, y, z = gt_boxes[:, 0], gt_boxes[:, 1], gt_boxes[:, 2]
coord_x = (x - self.point_cloud_range[0]) / self.voxel_size[0] / feature_map_stride
coord_y = (y - self.point_cloud_range[1]) / self.voxel_size[1] / feature_map_stride
coord_x = torch.clamp(coord_x, min=0, max=feature_map_size[0] - 0.5) # bugfixed: 1e-6 does not work for center.int()
coord_y = torch.clamp(coord_y, min=0, max=feature_map_size[1] - 0.5) #
center = torch.cat((coord_x[:, None], coord_y[:, None]), dim=-1)
center_int = center.int()
center_int_float = center_int.float()
dx, dy, dz = gt_boxes[:, 3], gt_boxes[:, 4], gt_boxes[:, 5]
dx = dx / self.voxel_size[0] / feature_map_stride
dy = dy / self.voxel_size[1] / feature_map_stride
radius = centernet_utils.gaussian_radius(dx, dy, min_overlap=gaussian_overlap)
radius = torch.clamp_min(radius.int(), min=min_radius)
for k in range(min(num_max_objs, gt_boxes.shape[0])):
if dx[k] <= 0 or dy[k] <= 0:
continue
if not (0 <= center_int[k][0] <= feature_map_size[0] and 0 <= center_int[k][1] <= feature_map_size[1]):
continue
cur_class_id = (gt_boxes[k, -1] - 1).long()
centernet_utils.draw_gaussian_to_heatmap(heatmap[cur_class_id], center[k], radius[k].item())
inds[k] = center_int[k, 1] * feature_map_size[0] + center_int[k, 0]
mask[k] = 1
ret_boxes[k, 0:2] = center[k] - center_int_float[k].float()
ret_boxes[k, 2] = z[k]
ret_boxes[k, 3:6] = gt_boxes[k, 3:6].log()
ret_boxes[k, 6] = torch.cos(gt_boxes[k, 6])
ret_boxes[k, 7] = torch.sin(gt_boxes[k, 6])
if gt_boxes.shape[1] > 8:
ret_boxes[k, 8:] = gt_boxes[k, 7:-1]
return heatmap, ret_boxes, inds, mask
def assign_targets(self, gt_boxes, feature_map_size=None, **kwargs):
"""
Args:
gt_boxes: (B, M, 8)
range_image_polar: (B, 3, H, W)
feature_map_size: (2) [H, W]
spatial_cartesian: (B, 4, H, W)
Returns:
"""
feature_map_size = feature_map_size[::-1] # [H, W] ==> [x, y]
target_assigner_cfg = self.model_cfg.TARGET_ASSIGNER_CONFIG
# feature_map_size = self.grid_size[:2] // target_assigner_cfg.FEATURE_MAP_STRIDE
batch_size = gt_boxes.shape[0]
ret_dict = {
'heatmaps': [],
'target_boxes': [],
'inds': [],
'masks': [],
'heatmap_masks': []
}
all_names = np.array(['bg', *self.class_names])
for idx, cur_class_names in enumerate(self.class_names_each_head):
heatmap_list, target_boxes_list, inds_list, masks_list = [], [], [], []
for bs_idx in range(batch_size):
cur_gt_boxes = gt_boxes[bs_idx]
gt_class_names = all_names[cur_gt_boxes[:, -1].cpu().long().numpy()]
gt_boxes_single_head = []
for idx, name in enumerate(gt_class_names):
if name not in cur_class_names:
continue
temp_box = cur_gt_boxes[idx]
temp_box[-1] = cur_class_names.index(name) + 1
gt_boxes_single_head.append(temp_box[None, :])
if len(gt_boxes_single_head) == 0:
gt_boxes_single_head = cur_gt_boxes[:0, :]
else:
gt_boxes_single_head = torch.cat(gt_boxes_single_head, dim=0)
heatmap, ret_boxes, inds, mask = self.assign_target_of_single_head(
num_classes=len(cur_class_names), gt_boxes=gt_boxes_single_head.cpu(),
feature_map_size=feature_map_size, feature_map_stride=target_assigner_cfg.FEATURE_MAP_STRIDE,
num_max_objs=target_assigner_cfg.NUM_MAX_OBJS,
gaussian_overlap=target_assigner_cfg.GAUSSIAN_OVERLAP,
min_radius=target_assigner_cfg.MIN_RADIUS,
)
heatmap_list.append(heatmap.to(gt_boxes_single_head.device))
target_boxes_list.append(ret_boxes.to(gt_boxes_single_head.device))
inds_list.append(inds.to(gt_boxes_single_head.device))
masks_list.append(mask.to(gt_boxes_single_head.device))
ret_dict['heatmaps'].append(torch.stack(heatmap_list, dim=0))
ret_dict['target_boxes'].append(torch.stack(target_boxes_list, dim=0))
ret_dict['inds'].append(torch.stack(inds_list, dim=0))
ret_dict['masks'].append(torch.stack(masks_list, dim=0))
return ret_dict
def sigmoid(self, x):
y = torch.clamp(x.sigmoid(), min=1e-4, max=1 - 1e-4)
return y
def get_loss(self):
pred_dicts = self.forward_ret_dict['pred_dicts']
target_dicts = self.forward_ret_dict['target_dicts']
tb_dict = {}
loss = 0
for idx, pred_dict in enumerate(pred_dicts):
pred_dict['hm'] = self.sigmoid(pred_dict['hm'])
hm_loss = self.hm_loss_func(pred_dict['hm'], target_dicts['heatmaps'][idx])
hm_loss *= self.model_cfg.LOSS_CONFIG.LOSS_WEIGHTS['cls_weight']
target_boxes = target_dicts['target_boxes'][idx]
pred_boxes = torch.cat([pred_dict[head_name] for head_name in self.separate_head_cfg.HEAD_ORDER], dim=1)
reg_loss = self.reg_loss_func(
pred_boxes, target_dicts['masks'][idx], target_dicts['inds'][idx], target_boxes
)
loc_loss = (reg_loss * reg_loss.new_tensor(self.model_cfg.LOSS_CONFIG.LOSS_WEIGHTS['code_weights'])).sum()
loc_loss = loc_loss * self.model_cfg.LOSS_CONFIG.LOSS_WEIGHTS['loc_weight']
loss += hm_loss + loc_loss
tb_dict['hm_loss_head_%d' % idx] = hm_loss.item()
tb_dict['loc_loss_head_%d' % idx] = loc_loss.item()
tb_dict['rpn_loss'] = loss.item()
return loss, tb_dict
def generate_predicted_boxes(self, batch_size, pred_dicts):
post_process_cfg = self.model_cfg.POST_PROCESSING
post_center_limit_range = torch.tensor(post_process_cfg.POST_CENTER_LIMIT_RANGE).cuda().float()
ret_dict = [{
'pred_boxes': [],
'pred_scores': [],
'pred_labels': [],
} for k in range(batch_size)]
for idx, pred_dict in enumerate(pred_dicts):
batch_hm = pred_dict['hm'].sigmoid()
batch_center = pred_dict['center']
batch_center_z = pred_dict['center_z']
batch_dim = pred_dict['dim'].exp()
batch_rot_cos = pred_dict['rot'][:, 0].unsqueeze(dim=1)
batch_rot_sin = pred_dict['rot'][:, 1].unsqueeze(dim=1)
batch_vel = pred_dict['vel'] if 'vel' in self.separate_head_cfg.HEAD_ORDER else None
final_pred_dicts = centernet_utils.decode_bbox_from_heatmap(
heatmap=batch_hm, rot_cos=batch_rot_cos, rot_sin=batch_rot_sin,
center=batch_center, center_z=batch_center_z, dim=batch_dim, vel=batch_vel,
point_cloud_range=self.point_cloud_range, voxel_size=self.voxel_size,
feature_map_stride=self.feature_map_stride,
K=post_process_cfg.MAX_OBJ_PER_SAMPLE,
circle_nms=(post_process_cfg.NMS_CONFIG.NMS_TYPE == 'circle_nms'),
score_thresh=post_process_cfg.SCORE_THRESH,
post_center_limit_range=post_center_limit_range
)
for k, final_dict in enumerate(final_pred_dicts):
final_dict['pred_labels'] = self.class_id_mapping_each_head[idx][final_dict['pred_labels'].long()]
if post_process_cfg.NMS_CONFIG.NMS_TYPE != 'circle_nms':
selected, selected_scores = model_nms_utils.class_agnostic_nms(
box_scores=final_dict['pred_scores'], box_preds=final_dict['pred_boxes'],
nms_config=post_process_cfg.NMS_CONFIG,
score_thresh=None
)
final_dict['pred_boxes'] = final_dict['pred_boxes'][selected]
final_dict['pred_scores'] = selected_scores
final_dict['pred_labels'] = final_dict['pred_labels'][selected]
ret_dict[k]['pred_boxes'].append(final_dict['pred_boxes'])
ret_dict[k]['pred_scores'].append(final_dict['pred_scores'])
ret_dict[k]['pred_labels'].append(final_dict['pred_labels'])
for k in range(batch_size):
ret_dict[k]['pred_boxes'] = torch.cat(ret_dict[k]['pred_boxes'], dim=0)
ret_dict[k]['pred_scores'] = torch.cat(ret_dict[k]['pred_scores'], dim=0)
ret_dict[k]['pred_labels'] = torch.cat(ret_dict[k]['pred_labels'], dim=0) + 1
return ret_dict
@staticmethod
def reorder_rois_for_refining(batch_size, pred_dicts):
num_max_rois = max([len(cur_dict['pred_boxes']) for cur_dict in pred_dicts])
num_max_rois = max(1, num_max_rois) # at least one faked rois to avoid error
pred_boxes = pred_dicts[0]['pred_boxes']
rois = pred_boxes.new_zeros((batch_size, num_max_rois, pred_boxes.shape[-1]))
roi_scores = pred_boxes.new_zeros((batch_size, num_max_rois))
roi_labels = pred_boxes.new_zeros((batch_size, num_max_rois)).long()
for bs_idx in range(batch_size):
num_boxes = len(pred_dicts[bs_idx]['pred_boxes'])
rois[bs_idx, :num_boxes, :] = pred_dicts[bs_idx]['pred_boxes']
roi_scores[bs_idx, :num_boxes] = pred_dicts[bs_idx]['pred_scores']
roi_labels[bs_idx, :num_boxes] = pred_dicts[bs_idx]['pred_labels']
return rois, roi_scores, roi_labels
def forward(self, data_dict):
spatial_features_2d = data_dict['spatial_features_2d']
x = self.shared_conv(spatial_features_2d)
pred_dicts = []
for head in self.heads_list:
pred_dicts.append(head(x))
if self.training:
target_dict = self.assign_targets(
data_dict['gt_boxes'], feature_map_size=spatial_features_2d.size()[2:],
feature_map_stride=data_dict.get('spatial_features_2d_strides', None)
)
self.forward_ret_dict['target_dicts'] = target_dict
self.forward_ret_dict['pred_dicts'] = pred_dicts
if not self.training or self.predict_boxes_when_training:
pred_dicts = self.generate_predicted_boxes(
data_dict['batch_size'], pred_dicts
)
if self.predict_boxes_when_training:
rois, roi_scores, roi_labels = self.reorder_rois_for_refining(data_dict['batch_size'], pred_dicts)
data_dict['rois'] = rois
data_dict['roi_scores'] = roi_scores
data_dict['roi_labels'] = roi_labels
data_dict['has_class_labels'] = True
else:
data_dict['final_box_dicts'] = pred_dicts
return data_dict