怎么看mmdetection版本_mmdetection源码阅读笔记(2)--Loss

之前做完比赛过后计划看看mmdetection的源码写点blog,写了两篇过后忙其他事去了,这里就接着把之前没写完的东西补上。

之前写了模型和网络的创建,这里就主要写下训练过程中具体的loss,主要分为以下几部分

RPN_loss

bbox_loss

mask_loss

RPN_loss

rpn_loss的实现具体定义在mmdet/models/anchor_head/rpn_head.py

def loss(self,

cls_scores,

bbox_preds,

gt_bboxes,

img_metas,

cfg,

gt_bboxes_ignore=None):

losses = super(RPNHead, self).loss(

cls_scores,

bbox_preds,

gt_bboxes,

None,

img_metas,

cfg,

gt_bboxes_ignore=gt_bboxes_ignore)

return dict(

loss_rpn_cls=losses['loss_cls'], loss_rpn_bbox=losses['loss_bbox'])

具体的计算方式定义在其父类mmdet/models/anchor_heads/anchor_head.py,主要是loss和loss_single两个函数。

先看loss函数

def loss(self,

cls_scores,

bbox_preds,

gt_bboxes,

gt_labels,

img_metas,

cfg,

gt_bboxes_ignore=None):

featmap_sizes = [featmap.size()[-2:] for featmap in cls_scores]

assert len(featmap_sizes) == len(self.anchor_generators)

anchor_list, valid_flag_list = self.get_anchors(

featmap_sizes, img_metas)

label_channels = self.cls_out_channels if self.use_sigmoid_cls else 1

cls_reg_targets = anchor_target(

anchor_list,

valid_flag_list,

gt_bboxes,

img_metas,

self.target_means,

self.target_stds,

cfg,

gt_bboxes_ignore_list=gt_bboxes_ignore,

gt_labels_list=gt_labels,

label_channels=label_channels,

sampling=self.sampling)

if cls_reg_targets is None:

return None

(labels_list, label_weights_list, bbox_targets_list, bbox_weights_list,

num_total_pos, num_total_neg) = cls_reg_targets

num_total_samples = (

num_total_pos + num_total_neg if self.sampling else num_total_pos)

losses_cls, losses_bbox = multi_apply(

self.loss_single,

cls_scores,

bbox_preds,

labels_list,

label_weights_list,

bbox_targets_list,

bbox_weights_list,

num_total_samples=num_total_samples,

cfg=cfg)

return dict(loss_cls=losses_cls, loss_bbox=losses_bbox)

这个主要做了两个事

生成anchor 和对应的 target

计算loss

首先,在此时rpn的输出为feature map中每个位置的anchor 分类的score以及该anchor 的bbox的修正值,我们要通过和gt计算loss来优化我们的网络,但是我们的gt是一堆人工标注的bbox,无法直接计算loss。所以,我们应该要先获取到anchor 然后将这些anchor 和 gt 对比在分别得到正负样本以及对应的target,之后我们才能计算得到loss。

所以第一步通过anchor_list, valid_flag_list = self.get_anchors(featmap_sizes, img_metas) 获取到了所有的anchor 以及一个 是否有效的flag (根据bbox是否超出图片边界来计算。)

拿到了所有的anchor之后就是和gt对比来区分正负样本以及生成label了,通过定义在mmdet/core/anchor/anchor_target.py的anchor_target()实现。

在这个函数中调用assigner将anchor 和gt关联起来,得到正样本和负样本,并用sampler将这些结果进行封装,方便之后使用。

得到了target过后,就是计算loss了,在self.loss_single中,

def loss_single(self, cls_score, bbox_pred, labels, label_weights,

bbox_targets, bbox_weights, num_total_samples, cfg):

# classification loss

labels = labels.reshape(-1)

label_weights = label_weights.reshape(-1)

cls_score = cls_score.permute(0, 2, 3,

1).reshape(-1, self.cls_out_channels)

loss_cls = self.loss_cls(

cls_score, labels, label_weights, avg_factor=num_total_samples)

# regression loss

bbox_targets = bbox_targets.reshape(-1, 4)

bbox_weights = bbox_weights.reshape(-1, 4)

bbox_pred = bbox_pred.permute(0, 2, 3, 1).reshape(-1, 4)

loss_bbox = self.loss_bbox(

bbox_pred,

bbox_targets,

bbox_weights,

avg_factor=num_total_samples)

return loss_cls, loss_bbox

这里用的loss就是常见的CrossEntropyLoss和SmoothL1Loss

bbox_loss

之前的rpn_loss是对候选框的第一次修正,这里的bbox_loss就是第二次修正了,两者的实际差别主要体现在分类上,在rpn阶段只分两类(前景和背景),这里分类数为N+1(真实类别+背景)

具体定义在mmdet/models/bbox_heads/bbox_head.py

def loss(self,

cls_score,

bbox_pred,

labels,

label_weights,

bbox_targets,

bbox_weights,

reduce=True):

losses = dict()

if cls_score is not None:

losses['loss_cls'] = self.loss_cls(

cls_score, labels, label_weights, reduce=reduce)

losses['acc'] = accuracy(cls_score, labels)

if bbox_pred is not None:

pos_inds = labels > 0

if self.reg_class_agnostic:

pos_bbox_pred = bbox_pred.view(bbox_pred.size(0), 4)[pos_inds]

else:

pos_bbox_pred = bbox_pred.view(bbox_pred.size(0), -1,

4)[pos_inds, labels[pos_inds]]

losses['loss_bbox'] = self.loss_bbox(

pos_bbox_pred,

bbox_targets[pos_inds],

bbox_weights[pos_inds],

avg_factor=bbox_targets.size(0))

return losses

可以看到和rpn loss相比,这里要简单很多,因为这里只包含了rpn loss中实际计算loss的部分,但是他也同样需要rpn中的assign和sample操作,两者的区别只是assign的输入不同,rpn的assign输入是该图所有的anchor, bbox部分assign的输入就是rpn的输出。这里的loss和rpn中的计算方式完全一样,就不在赘述了。

mask_loss

mask部分计算loss之前也有一个获取target的步骤。

mmdet/models/mask_heads/fcn_mask_head.py

def get_target(self, sampling_results, gt_masks, rcnn_train_cfg):

pos_proposals = [res.pos_bboxes for res in sampling_results]

pos_assigned_gt_inds = [

res.pos_assigned_gt_inds for res in sampling_results

]

mask_targets = mask_target(pos_proposals, pos_assigned_gt_inds,

gt_masks, rcnn_train_cfg)

return mask_targets

这里获取target相对之前来说就要简单点了,通过定义在mmdet/core/mask/mask_target.py的mask_target()取到和prooisals相同大小的mask就行了。

def mask_target(pos_proposals_list, pos_assigned_gt_inds_list, gt_masks_list,

cfg):

cfg_list = [cfg for _ in range(len(pos_proposals_list))]

mask_targets = map(mask_target_single, pos_proposals_list,

pos_assigned_gt_inds_list, gt_masks_list, cfg_list)

mask_targets = torch.cat(list(mask_targets))

return mask_targets

def mask_target_single(pos_proposals, pos_assigned_gt_inds, gt_masks, cfg):

mask_size = cfg.mask_size

num_pos = pos_proposals.size(0)

mask_targets = []

if num_pos > 0:

proposals_np = pos_proposals.cpu().numpy()

pos_assigned_gt_inds = pos_assigned_gt_inds.cpu().numpy()

for i in range(num_pos):

gt_mask = gt_masks[pos_assigned_gt_inds[i]]

bbox = proposals_np[i, :].astype(np.int32)

x1, y1, x2, y2 = bbox

w = np.maximum(x2 - x1 + 1, 1)

h = np.maximum(y2 - y1 + 1, 1)

# mask is uint8 both before and after resizing

target = mmcv.imresize(gt_mask[y1:y1 + h, x1:x1 + w],

(mask_size, mask_size))

mask_targets.append(target)

mask_targets = torch.from_numpy(np.stack(mask_targets)).float().to(

pos_proposals.device)

else:

mask_targets = pos_proposals.new_zeros((0, mask_size, mask_size))

return mask_targets

而loss部分也比较简单,也是用的CrossEntropyLoss。

def loss(self, mask_pred, mask_targets, labels):

loss = dict()

if self.class_agnostic:

loss_mask = self.loss_mask(mask_pred, mask_targets,

torch.zeros_like(labels))

else:

loss_mask = self.loss_mask(mask_pred, mask_targets, labels)

loss['loss_mask'] = loss_mask

return loss

总结

总的来说这些loss还是算比较好理解的,看起来有三部分的loss,但是实际上每个部分的都差不多。

下一篇就准备写下整个的训练流程了,相当于将前面这三篇给连起来,有个更具体的理解。

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