libtorch (pytorch c++) 教程(七)

  • 第一章:开发环境搭建:VS+libtorch和Qt+libtorch
  • 第二章:张量的常规操作
  • 第三章:简单的CNN, MLP, LSTM模型搭建
  • 第四章:数据加载模块使用
  • 第五章:分类模型搭建,训练和预测
  • 第六章:分割模型搭建,训练和预测
  • 第七章:目标检测模型搭建,训练和预测
  • 第八章:总结和展望

    文章目录

      • 模型简介
      • 骨干网络
      • yolov4_tiny
      • 预测
      • 训练

阅读本文需要有基础的pytorch编程经验,目标检测框架相关知识,不用很深入,大致了解概念即可。

本章简要介绍如何如何用C++实现一个目标检测器模型,该模型具有训练和预测的功能。本文的分割模型架构使用yolov4-tiny结构,代码结构参考了bubbliiiing yolov4-tiny,本文分享的c++模型几乎完美复现了pytorch的版本,且具有速度优势,30-40%的速度提升。

模型简介

简单介绍一下yolov4-tiny模型。yolov4-tiny模型是YOLO(you only look once)系列模型中,version 4的轻巧版,相比于yolov4,它牺牲了部分精度以实现速度上的大幅提升。yolov4_tiny模型结构如图(图片来源自这):
[外链图片转存失败,源站可能有防盗链机制,建议将图片保存下来直接上传(img-XGhpI22W-1620215360286)(https://raw.githubusercontent.com/AllentDan/ImageBase/main/detection/yolo4_tiny.png)]
可以发现模型结构非常简单,以CSPDarknet53-tiny为骨干网络,FPN为颈部(neck),Yolo head为头部。最后输出两个特征层,分别是原图下采样32倍和下采样16倍的特征图。训练时,以这两个特征图分别输入损失计算中计算损失,再将损失求和(或平均,怎么都好),后做反向传播,预测时将两个特征图解码出的结果做并集再做NMS(非极大值抑制)。

骨干网络

CSPDarknet53-tiny是CSPNet的一种,CSPNet发表于CVPR2019,是用于提升目标检测模型检测性能的一种骨干网络。感兴趣的同学可以去看原文,简单理解该论文贡献,就是将特征层沿着通道维度切成两片,两片分别做不同的卷积,然后再拼接起来,这样做相比于直接对原图做特征提取,能减少计算量。

默认看过我的libtorch系列教程的前部分,直接上代码。首先是基本单元,由Conv2d + BatchNorm2d + LeakyReLU构成。

//Conv2d + BatchNorm2d + LeakyReLU
class BasicConvImpl : public torch::nn::Module {
public:
	BasicConvImpl(int in_channels, int out_channels, int kernel_size, int stride = 1);
	torch::Tensor forward(torch::Tensor x);
private:
	// Declare layers
	torch::nn::Conv2d conv{ nullptr };
	torch::nn::BatchNorm2d bn{ nullptr };
	torch::nn::LeakyReLU acitivation{ nullptr };
}; TORCH_MODULE(BasicConv);

BasicConvImpl::BasicConvImpl(int in_channels, int out_channels, int kernel_size, 
	int stride) :
	conv(conv_options(in_channels, out_channels, kernel_size, stride, 
		int(kernel_size / 2), 1, false)),
	bn(torch::nn::BatchNorm2d(out_channels)),
	acitivation(torch::nn::LeakyReLU(torch::nn::LeakyReLUOptions().negative_slope(0.1)))
{
	register_module("conv", conv);
	register_module("bn", bn);
}

torch::Tensor BasicConvImpl::forward(torch::Tensor x)
{
	x = conv->forward(x);
	x = bn->forward(x);
	x = acitivation(x);
	return x;
}

该层作为基本模块,将在后期作为搭积木的基本块,搭建yolo4_tiny。

然后是Resblock_body模块,

class Resblock_bodyImpl : public torch::nn::Module {
public:
	Resblock_bodyImpl(int in_channels, int out_channels);
	std::vector<torch::Tensor> forward(torch::Tensor x);
private:
	int out_channels;
	BasicConv conv1{ nullptr };
	BasicConv conv2{ nullptr };
	BasicConv conv3{ nullptr };
	BasicConv conv4{ nullptr };
	torch::nn::MaxPool2d maxpool{ nullptr };
}; TORCH_MODULE(Resblock_body);

Resblock_bodyImpl::Resblock_bodyImpl(int in_channels, int out_channels) {
	this->out_channels = out_channels;
	conv1 = BasicConv(in_channels, out_channels, 3);
	conv2 = BasicConv(out_channels / 2, out_channels / 2, 3);
	conv3 = BasicConv(out_channels / 2, out_channels / 2, 3);
	conv4 = BasicConv(out_channels, out_channels, 1);
	maxpool = torch::nn::MaxPool2d(maxpool_options(2, 2));

	register_module("conv1", conv1);
	register_module("conv2", conv2);
	register_module("conv3", conv3);
	register_module("conv4", conv4);

}
std::vector<torch::Tensor> Resblock_bodyImpl::forward(torch::Tensor x) {
	auto c = out_channels;
	x = conv1->forward(x);
	auto route = x;

	x = torch::split(x, c / 2, 1)[1];
	x = conv2->forward(x);
	auto route1 = x;

	x = conv3->forward(x);
	x = torch::cat({ x, route1 }, 1);
	x = conv4->forward(x);
	auto feat = x;

	x = torch::cat({ route, x }, 1);
	x = maxpool->forward(x);
	return std::vector<torch::Tensor>({ x,feat });
}

最后是骨干网络主体

class CSPdarknet53_tinyImpl : public torch::nn::Module
{
public:
	CSPdarknet53_tinyImpl();
	std::vector<torch::Tensor> forward(torch::Tensor x);
private:
	BasicConv conv1{ nullptr };
	BasicConv conv2{ nullptr };
	Resblock_body resblock_body1{ nullptr };
	Resblock_body resblock_body2{ nullptr };
	Resblock_body resblock_body3{ nullptr };
	BasicConv conv3{ nullptr };
	int num_features = 1;
}; TORCH_MODULE(CSPdarknet53_tiny);

CSPdarknet53_tinyImpl::CSPdarknet53_tinyImpl() {
	conv1 = BasicConv(3, 32, 3, 2);
	conv2 = BasicConv(32, 64, 3, 2);
	resblock_body1 = Resblock_body(64, 64);
	resblock_body2 = Resblock_body(128, 128);
	resblock_body3 = Resblock_body(256, 256);
	conv3 = BasicConv(512, 512, 3);

	register_module("conv1", conv1);
	register_module("conv2", conv2);
	register_module("resblock_body1", resblock_body1);
	register_module("resblock_body2", resblock_body2);
	register_module("resblock_body3", resblock_body3);
	register_module("conv3", conv3);
}

std::vector<torch::Tensor> CSPdarknet53_tinyImpl::forward(torch::Tensor x) {
	// 416, 416, 3 -> 208, 208, 32 -> 104, 104, 64
	x = conv1(x);
	x = conv2(x);

	// 104, 104, 64 -> 52, 52, 128
	x = resblock_body1->forward(x)[0];
	// 52, 52, 128 -> 26, 26, 256
	x = resblock_body2->forward(x)[0];
	// 26, 26, 256->xΪ13, 13, 512
#   //        -> feat1Ϊ26,26,256
	auto res_out = resblock_body3->forward(x);
	x = res_out[0];
	auto feat1 = res_out[1];
	// 13, 13, 512 -> 13, 13, 512
	x = conv3->forward(x);
	auto feat2 = x;
	return std::vector<torch::Tensor>({ feat1, feat2 });
}

至此,yolo4_tiny中的骨干网络已经搭建好。接下来将搭建yolo4_tiny模型。

yolov4_tiny

骨干网络得到的特征图,将经过FPN,需要上采样模块。

//conv+upsample
class UpsampleImpl : public torch::nn::Module {
public:
	UpsampleImpl(int in_channels, int out_channels);
	torch::Tensor forward(torch::Tensor x);
private:
	// Declare layers
	torch::nn::Sequential upsample = torch::nn::Sequential();
}; TORCH_MODULE(Upsample);

UpsampleImpl::UpsampleImpl(int in_channels, int out_channels)
{
	upsample = torch::nn::Sequential(
		BasicConv(in_channels, out_channels, 1)
		//torch::nn::Upsample(torch::nn::UpsampleOptions().scale_factor(std::vector({ 2 })).mode(torch::kNearest).align_corners(false))
	);
	register_module("upsample", upsample);
}

torch::Tensor UpsampleImpl::forward(torch::Tensor x)
{
	x = upsample->forward(x);
	x = at::upsample_nearest2d(x, { x.sizes()[2] * 2 , x.sizes()[3] * 2 });
	return x;
}

然后是yolo_head模块

torch::nn::Sequential yolo_head(std::vector<int> filters_list, int in_filters);

torch::nn::Sequential yolo_head(std::vector<int> filters_list, int in_filters) {
	auto m = torch::nn::Sequential(BasicConv(in_filters, filters_list[0], 3),
		torch::nn::Conv2d(conv_options(filters_list[0], filters_list[1], 1)));
	return m;
}

以及yolo_body

class YoloBody_tinyImpl : public torch::nn::Module {
public:
	YoloBody_tinyImpl(int num_anchors, int num_classes);
	std::vector<torch::Tensor> forward(torch::Tensor x);
private:
	// Declare layers
	CSPdarknet53_tiny backbone{ nullptr };
	BasicConv conv_for_P5{ nullptr };
	Upsample upsample{ nullptr };
	torch::nn::Sequential yolo_headP5{ nullptr };
	torch::nn::Sequential yolo_headP4{ nullptr };
}; TORCH_MODULE(YoloBody_tiny);

YoloBody_tinyImpl::YoloBody_tinyImpl(int num_anchors, int num_classes) {
	backbone = CSPdarknet53_tiny();
	conv_for_P5 = BasicConv(512, 256, 1);
	yolo_headP5 = yolo_head({ 512, num_anchors * (5 + num_classes) }, 256);
	upsample = Upsample(256, 128);
	yolo_headP4 = yolo_head({ 256, num_anchors * (5 + num_classes) }, 384);

	register_module("backbone", backbone);
	register_module("conv_for_P5", conv_for_P5);
	register_module("yolo_headP5", yolo_headP5);
	register_module("upsample", upsample);
	register_module("yolo_headP4", yolo_headP4);
}
std::vector<torch::Tensor> YoloBody_tinyImpl::forward(torch::Tensor x) {
	//return feat1 with shape of {26,26,256} and feat2 of {13, 13, 512}
	auto backbone_out = backbone->forward(x);
	auto feat1 = backbone_out[0];
	auto feat2 = backbone_out[1];
	//13,13,512 -> 13,13,256
	auto P5 = conv_for_P5->forward(feat2);
	//13, 13, 256 -> 13, 13, 512 -> 13, 13, 255
	auto out0 = yolo_headP5->forward(P5);


	//13,13,256 -> 13,13,128 -> 26,26,128
	auto P5_Upsample = upsample->forward(P5);
	//26, 26, 256 + 26, 26, 128 -> 26, 26, 384
	auto P4 = torch::cat({ P5_Upsample, feat1 }, 1);
	//26, 26, 384 -> 26, 26, 256 -> 26, 26, 255
	auto out1 = yolo_headP4->forward(P4);
	return std::vector<torch::Tensor>({ out0, out1 });
}

代码写到这一步,其实只要细心就会发现基本是对pytorch代码到libtorch的迁移,除了少数bug需要调试,大部分简单迁移到c++即可。可以说是非常简便了。

像前面章节中一样,生成torchscript模型。bubbliiiing yolov4-tiny中有提供一个coco训练版本,通过下述代码生成.pt文件:

import torch
from torchsummary import summary
import numpy as np

from nets.yolo4_tiny import YoloBody
from train import get_anchors, get_classes,YOLOLoss

device = torch.device('cpu')
model = YoloBody(3,80).to(device)
model_path = "model_data/yolov4_tiny_weights_coco.pth"

print('Loading weights into state dict...')
model_dict = model.state_dict()
pretrained_dict = torch.load(model_path, map_location=torch.device("cpu"))
pretrained_dict = {k: v for k, v in pretrained_dict.items() if np.shape(model_dict[k]) ==  np.shape(v)}
model_dict.update(pretrained_dict)
model.load_state_dict(model_dict)
print('Finished!')

#生成pt模型,按照官网来即可
model=model.to(torch.device("cpu"))
model.eval()
var=torch.ones((1,3,416,416))
traced_script_module = torch.jit.trace(model, var)
traced_script_module.save("yolo4_tiny.pt")

然后在c++中使用下述代码测试是否能够正确加载:

auto model = YoloBody_tiny(3, 80);
torch::load(model, "weights/yolo4_tiny.pt");

执行通过即表明加载成功。

预测

预测需要将YOLO4_tiny模型输出的张量进行解码,根据源代码解码函数,写出c++版本的解码函数,此时将发现,libtorch教程第二章的重要性了。

torch::Tensor DecodeBox(torch::Tensor input, torch::Tensor anchors, int num_classes, int img_size[])
{
	int num_anchors = anchors.sizes()[0];
	int bbox_attrs = 5 + num_classes;
	int batch_size = input.sizes()[0];
	int input_height = input.sizes()[2];
	int input_width = input.sizes()[3];
	//计算步长
	//每一个特征点对应原来的图片上多少个像素点
	//如果特征层为13x13的话,一个特征点就对应原来的图片上的32个像素点
	//416 / 13 = 32
	auto stride_h = img_size[1] / input_height;
	auto stride_w = img_size[0] / input_width;
	//把先验框的尺寸调整成特征层大小的形式
	//计算出先验框在特征层上对应的宽高
	auto scaled_anchors = anchors.clone();
	scaled_anchors.select(1, 0) = scaled_anchors.select(1, 0) / stride_w;
	scaled_anchors.select(1, 1) = scaled_anchors.select(1, 1) / stride_h;

	//bs, 3 * (5 + num_classes), 13, 13->bs, 3, 13, 13, (5 + num_classes)
	//cout << "begin view"<
	auto prediction = input.view({ batch_size, num_anchors,bbox_attrs, input_height, input_width }).permute({ 0, 1, 3, 4, 2 }).contiguous();
	//cout << "end view" << endl;
	//先验框的中心位置的调整参数
	auto x = torch::sigmoid(prediction.select(-1, 0));
	auto y = torch::sigmoid(prediction.select(-1, 1));
	//先验框的宽高调整参数
	auto w = prediction.select(-1, 2); // Width
	auto h = prediction.select(-1, 3); // Height

	//获得置信度,是否有物体
	auto conf = torch::sigmoid(prediction.select(-1, 4));
	//种类置信度
	auto pred_cls = torch::sigmoid(prediction.narrow(-1, 5, num_classes));// Cls pred.

	auto LongType = x.clone().to(torch::kLong).options();
	auto FloatType = x.options();

	//生成网格,先验框中心,网格左上角 batch_size, 3, 13, 13
	auto grid_x = torch::linspace(0, input_width - 1, input_width).repeat({ input_height, 1 }).repeat(
		{ batch_size * num_anchors, 1, 1 }).view(x.sizes()).to(FloatType);
	auto grid_y = torch::linspace(0, input_height - 1, input_height).repeat({ input_width, 1 }).t().repeat(
		{ batch_size * num_anchors, 1, 1 }).view(y.sizes()).to(FloatType);

	//生成先验框的宽高
	auto anchor_w = scaled_anchors.to(FloatType).narrow(1, 0, 1);
	auto anchor_h = scaled_anchors.to(FloatType).narrow(1, 1, 1);
	anchor_w = anchor_w.repeat({ batch_size, 1 }).repeat({ 1, 1, input_height * input_width }).view(w.sizes());
	anchor_h = anchor_h.repeat({ batch_size, 1 }).repeat({ 1, 1, input_height * input_width }).view(h.sizes());

	//计算调整后的先验框中心与宽高
	auto pred_boxes = torch::randn_like(prediction.narrow(-1, 0, 4)).to(FloatType);
	pred_boxes.select(-1, 0) = x + grid_x;
	pred_boxes.select(-1, 1) = y + grid_y;
	pred_boxes.select(-1, 2) = w.exp() * anchor_w;
	pred_boxes.select(-1, 3) = h.exp() * anchor_h;

	//用于将输出调整为相对于416x416的大小
	std::vector<int> scales{ stride_w, stride_h, stride_w, stride_h };
	auto _scale = torch::tensor(scales).to(FloatType);
	//cout << pred_boxes << endl;
	//cout << conf << endl;
	//cout << pred_cls << endl;
	pred_boxes = pred_boxes.view({ batch_size, -1, 4 }) * _scale;
	conf = conf.view({ batch_size, -1, 1 });
	pred_cls = pred_cls.view({ batch_size, -1, num_classes });
	auto output = torch::cat({ pred_boxes, conf, pred_cls }, -1);
	return output;
}

此外,还需要将输出进行非极大值抑制。参考我的NMS的几种写法写出非极大值抑制函数:

std::vector<int> nms_libtorch(torch::Tensor bboxes, torch::Tensor scores, float thresh) {
	auto x1 = bboxes.select(-1, 0);
	auto y1 = bboxes.select(-1, 1);
	auto x2 = bboxes.select(-1, 2);
	auto y2 = bboxes.select(-1, 3);
	auto areas = (x2 - x1)*(y2 - y1);   //[N, ] 每个bbox的面积
	auto tuple_sorted = scores.sort(0, true);    //降序排列
	auto order = std::get<1>(tuple_sorted);

	std::vector<int>	keep;
	while (order.numel() > 0) {// torch.numel()返回张量元素个数
		if (order.numel() == 1) {//    保留框只剩一个
			auto i = order.item();
			keep.push_back(i.toInt());
			break;
		}
		else {
			auto i = order[0].item();// 保留scores最大的那个框box[i]
			keep.push_back(i.toInt());
		}
		//计算box[i]与其余各框的IOU(思路很好)
		auto order_mask = order.narrow(0, 1, order.size(-1) - 1);
		x1.index({ order_mask });
		x1.index({ order_mask }).clamp(x1[keep.back()].item().toFloat(), 1e10);
		auto xx1 = x1.index({ order_mask }).clamp(x1[keep.back()].item().toFloat(), 1e10);// [N - 1, ]
		auto yy1 = y1.index({ order_mask }).clamp(y1[keep.back()].item().toFloat(), 1e10);
		auto xx2 = x2.index({ order_mask }).clamp(0, x2[keep.back()].item().toFloat());
		auto yy2 = y2.index({ order_mask }).clamp(0, y2[keep.back()].item().toFloat());
		auto inter = (xx2 - xx1).clamp(0, 1e10) * (yy2 - yy1).clamp(0, 1e10);// [N - 1, ]

		auto iou = inter / (areas[keep.back()] + areas.index({ order.narrow(0,1,order.size(-1) - 1) }) - inter);//[N - 1, ]
		auto idx = (iou <= thresh).nonzero().squeeze();//注意此时idx为[N - 1, ] 而order为[N, ]
		if (idx.numel() == 0) {
			break;
		}
		order = order.index({ idx + 1 }); //修补索引之间的差值
	}
	return keep;
}

std::vector<torch::Tensor> non_maximum_suppression(torch::Tensor prediction, int num_classes, float conf_thres, float nms_thres) {

	prediction.select(-1, 0) -= prediction.select(-1, 2) / 2;
	prediction.select(-1, 1) -= prediction.select(-1, 3) / 2;
	prediction.select(-1, 2) += prediction.select(-1, 0);
	prediction.select(-1, 3) += prediction.select(-1, 1);

	std::vector<torch::Tensor> output;
	for (int image_id = 0; image_id < prediction.sizes()[0]; image_id++) {
		auto image_pred = prediction[image_id];
		auto max_out_tuple = torch::max(image_pred.narrow(-1, 5, num_classes), -1, true);
		auto class_conf = std::get<0>(max_out_tuple);
		auto class_pred = std::get<1>(max_out_tuple);
		auto conf_mask = (image_pred.select(-1, 4) * class_conf.select(-1, 0) >= conf_thres).squeeze();
		image_pred = image_pred.index({ conf_mask }).to(torch::kFloat);
		class_conf = class_conf.index({ conf_mask }).to(torch::kFloat);
		class_pred = class_pred.index({ conf_mask }).to(torch::kFloat);

		if (!image_pred.sizes()[0]) {
			output.push_back(torch::full({ 1, 7 }, 0));
			continue;
		}

		//获得的内容为(x1, y1, x2, y2, obj_conf, class_conf, class_pred)
		auto detections = torch::cat({ image_pred.narrow(-1,0,5), class_conf, class_pred }, 1);
		//获得种类
		std::vector<torch::Tensor> img_classes;

		for (int m = 0, len = detections.size(0); m < len; m++)
		{
			bool found = false;
			for (size_t n = 0; n < img_classes.size(); n++)
			{
				auto ret = (detections[m][6] == img_classes[n]);
				if (torch::nonzero(ret).size(0) > 0)
				{
					found = true;
					break;
				}
			}
			if (!found) img_classes.push_back(detections[m][6]);
		}
		std::vector<torch::Tensor> temp_class_detections;
		for (auto c : img_classes) {
			auto detections_class = detections.index({ detections.select(-1,-1) == c });
			auto keep = nms_libtorch(detections_class.narrow(-1, 0, 4), detections_class.select(-1, 4)*detections_class.select(-1, 5), nms_thres);
			std::vector<torch::Tensor> temp_max_detections;
			for (auto v : keep) {
				temp_max_detections.push_back(detections_class[v]);
			}
			auto max_detections = torch::cat(temp_max_detections, 0);
			temp_class_detections.push_back(max_detections);
		}
		auto class_detections = torch::cat(temp_class_detections, 0);
		output.push_back(class_detections);
	}
	return output;
}

这些函数准备好后,写出预测函数:

void show_bbox_coco(cv::Mat image, torch::Tensor bboxes, int nums) {
	//设置绘制文本的相关参数
	int font_face = cv::FONT_HERSHEY_COMPLEX;
	double font_scale = 0.4;
	int thickness = 1;
	float* bbox = new float[bboxes.size(0)]();
	std::cout << bboxes << std::endl;
	memcpy(bbox, bboxes.cpu().data_ptr(), bboxes.size(0) * sizeof(float));
	for (int i = 0; i < bboxes.size(0); i = i + 7)
	{
		cv::rectangle(image, cv::Rect(bbox[i + 0], bbox[i + 1], bbox[i + 2] - bbox[i + 0], bbox[i + 3] - bbox[i + 1]), cv::Scalar(0, 0, 255));
		//将文本框居中绘制
		cv::Point origin;
		origin.x = bbox[i + 0];
		origin.y = bbox[i + 1] + 8;
		cv::putText(image, std::to_string(int(bbox[i + 6])), origin, font_face, font_scale, cv::Scalar(0, 0, 255), thickness, 1, 0);
	}
	delete bbox;
	cv::imshow("test", image);
	cv::waitKey(0);
	cv::destroyAllWindows();
}

void Predict(YoloBody_tiny detector, cv::Mat image, bool show, float conf_thresh, float nms_thresh) {
	int origin_width = image.cols;
	int origin_height = image.rows;
	cv::resize(image, image, { 416,416 });
	auto img_tensor = torch::from_blob(image.data, { image.rows, image.cols, 3 }, torch::kByte);
	img_tensor = img_tensor.permute({ 2, 0, 1 }).unsqueeze(0).to(torch::kFloat) / 255.0;

	float anchor[12] = { 10,14,  23,27,  37,58,  81,82,  135,169,  344,319 };
	auto anchors_ = torch::from_blob(anchor, { 6,2 }, torch::TensorOptions(torch::kFloat32));
	int image_size[2] = { 416,416 };
	img_tensor = img_tensor.cuda();

	auto outputs = detector->forward(img_tensor);
	std::vector<torch::Tensor> output_list = {};
	auto tensor_input = outputs[1];
	auto output_decoded = DecodeBox(tensor_input, anchors_.narrow(0, 0, 3), 80, image_size);
	output_list.push_back(output_decoded);

	tensor_input = outputs[0];
	output_decoded = DecodeBox(tensor_input, anchors_.narrow(0, 3, 3), 80, image_size);
	output_list.push_back(output_decoded);

	//std::cout << tensor_input << anchors_.narrow(0, 3, 3);

	auto output = torch::cat(output_list, 1);
	auto detection = non_maximum_suppression(output, 80, conf_thresh, nms_thresh);

	float w_scale = float(origin_width) / 416;
	float h_scale = float(origin_height) / 416;
	for (int i = 0; i < detection.size(); i++) {
		for (int j = 0; j < detection[i].size(0) / 7; j++)
		{
			detection[i].select(0, 7 * j + 0) *= w_scale;
			detection[i].select(0, 7 * j + 1) *= h_scale;
			detection[i].select(0, 7 * j + 2) *= w_scale;
			detection[i].select(0, 7 * j + 3) *= h_scale;
		}
	}

	cv::resize(image, image, { origin_width,origin_height });
	if (show)
		show_bbox_coco(image, detection[0], 80);
	return;
}

使用VOC数据集中一张图片,测试一下函数准确性。直接将上述代码用于测试.pt文件,如输入下述代码:

cv::Mat image = cv::imread("2007_005331.jpg");
auto model = YoloBody_tiny(3, 80);
torch::load(model, "weights/yolo4_tiny.pt");
model->to(torch::kCUDA);
Predict(model, image, true, 0.1, 0.3);

使用的图片如下图
libtorch (pytorch c++) 教程(七)_第1张图片

将会发现,预测结果如下:
libtorch (pytorch c++) 教程(七)_第2张图片

结果分析有以下两点结论:

  • 输出了检测框,预测函数大概率正确;
  • 存在部分误检,提高置信度阈值可能改善,但是会漏检。这是由于.pt文件训练时采用的预处理策略,和本文代码预测时采用的预处理策略不一致导致的。

使用训练和预测一致的预处理方式处理图片,得到的结果应该要好很多。下面时一张,以coco预训练权重做迁移学习,只训练yolo_head,训练voc数据集一个周期后,预测该图的效果:
libtorch (pytorch c++) 教程(七)_第3张图片

继续训练,数据增强,训练全部权重应该可以将结果提升更多。

训练

训练代码比较多,博客就不再介绍。可以移步到LibtorchTutorials中。同时,LibtorchTutorials中的代码实现的功能都比较基础,我将分开在LibtorchSegment项目和LibtorchDetection中将功能提升完善。有帮助到的话请点个star资瓷下。

分享不易,如果有用请不吝给我一个,转载注明出处:https://allentdan.github.io/
代码见LibtorchTutorials

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