#include #include #include #include #include #include namespace migraphxSamples { DetectorYOLOV7::DetectorYOLOV7() { } DetectorYOLOV7::~DetectorYOLOV7() { configurationFile.release(); } ErrorCode DetectorYOLOV7::Initialize(InitializationParameterOfDetector initializationParameterOfDetector) { // 读取配置文件 std::string configFilePath=initializationParameterOfDetector.configFilePath; if(Exists(configFilePath)==false) { LOG_ERROR(stdout, "no configuration file!\n"); return CONFIG_FILE_NOT_EXIST; } if(!configurationFile.open(configFilePath, cv::FileStorage::READ)) { LOG_ERROR(stdout, "fail to open configuration file\n"); return FAIL_TO_OPEN_CONFIG_FILE; } LOG_INFO(stdout, "succeed to open configuration file\n"); // 获取配置文件参数 cv::FileNode netNode = configurationFile["DetectorYOLOV7"]; std::string modelPath=(std::string)netNode["ModelPath"]; std::string pathOfClassNameFile=(std::string)netNode["ClassNameFile"]; yolov7Parameter.confidenceThreshold = (float)netNode["ConfidenceThreshold"]; yolov7Parameter.nmsThreshold = (float)netNode["NMSThreshold"]; yolov7Parameter.objectThreshold = (float)netNode["ObjectThreshold"]; yolov7Parameter.numberOfClasses=(int)netNode["NumberOfClasses"]; useFP16=(bool)(int)netNode["UseFP16"]; // 加载模型 if(Exists(modelPath)==false) { LOG_ERROR(stdout,"%s not exist!\n",modelPath.c_str()); return MODEL_NOT_EXIST; } net = migraphx::parse_onnx(modelPath); LOG_INFO(stdout,"succeed to load model: %s\n",GetFileName(modelPath).c_str()); // 获取模型输入属性 std::unordered_map inputMap=net.get_parameter_shapes(); inputName=inputMap.begin()->first; inputShape=inputMap.begin()->second; int N=inputShape.lens()[0]; int C=inputShape.lens()[1]; int H=inputShape.lens()[2]; int W=inputShape.lens()[3]; inputSize=cv::Size(W,H); // 设置模型为GPU模式 migraphx::target gpuTarget = migraphx::gpu::target{}; // 量化 if(useFP16) { migraphx::quantize_fp16(net); } // 编译模型 migraphx::compile_options options; options.device_id=0; // 设置GPU设备,默认为0号设备 options.offload_copy=true; net.compile(gpuTarget,options); LOG_INFO(stdout,"succeed to compile model: %s\n",GetFileName(modelPath).c_str()); // warm up std::unordered_map inputData; inputData[inputName]=migraphx::argument{inputShape}; net.eval(inputData); // 读取类别名 if(!pathOfClassNameFile.empty()) { std::ifstream classNameFile(pathOfClassNameFile); std::string line; while (getline(classNameFile, line)) { classNames.push_back(line); } } else { classNames.resize(yolov7Parameter.numberOfClasses); } // log LOG_INFO(stdout,"InputSize:%dx%d\n",inputSize.width,inputSize.height); LOG_INFO(stdout,"InputName:%s\n",inputName.c_str()); LOG_INFO(stdout,"ConfidenceThreshold:%f\n",yolov7Parameter.confidenceThreshold); LOG_INFO(stdout,"objectThreshold:%f\n",yolov7Parameter.objectThreshold); LOG_INFO(stdout,"NMSThreshold:%f\n",yolov7Parameter.nmsThreshold); LOG_INFO(stdout,"NumberOfClasses:%d\n",yolov7Parameter.numberOfClasses); return SUCCESS; } ErrorCode DetectorYOLOV7::Detect(const cv::Mat &srcImage, std::vector &resultsOfDetection) { if(srcImage.empty()||srcImage.type()!=CV_8UC3) { LOG_ERROR(stdout, "image error!\n"); return IMAGE_ERROR; } // 数据预处理并转换为NCHW格式 cv::Mat inputBlob; cv::dnn::blobFromImage(srcImage, inputBlob, 1 / 255.0, inputSize, cv::Scalar(0, 0, 0), true, false); // 创建输入数据 std::unordered_map inputData; inputData[inputName]= migraphx::argument{inputShape, (float*)inputBlob.data}; // 推理 std::vector inferenceResults = net.eval(inputData); // 获取推理结果 std::vector outs; migraphx::argument result = inferenceResults[0]; // 转换为cv::Mat migraphx::shape outputShape = result.get_shape(); int shape[]={outputShape.lens()[0],outputShape.lens()[1],outputShape.lens()[2]}; cv::Mat out(3,shape,CV_32F); memcpy(out.data,result.data(),sizeof(float)*outputShape.elements()); outs.push_back(out); //获取先验框的个数 int numProposal = outs[0].size[1]; int numOut = outs[0].size[2]; //变换输出的维度 outs[0] = outs[0].reshape(0, numProposal); //生成先验框 std::vector confidences; std::vector boxes; std::vector classIds; float ratioh = (float)srcImage.rows / inputSize.height, ratiow = (float)srcImage.cols / inputSize.width; //计算cx,cy,w,h,box_sore,class_sore int n = 0, rowInd = 0; float* pdata = (float*)outs[0].data; for (n = 0; n < numProposal; n++) { float boxScores = pdata[4]; if (boxScores > yolov7Parameter.objectThreshold) { cv::Mat scores = outs[0].row(rowInd).colRange(5, numOut); cv::Point classIdPoint; double maxClassScore; cv::minMaxLoc(scores, 0, &maxClassScore, 0, &classIdPoint); maxClassScore *= boxScores; if (maxClassScore > yolov7Parameter.confidenceThreshold) { const int classIdx = classIdPoint.x; float cx = pdata[0] * ratiow; float cy = pdata[1] * ratioh; float w = pdata[2] * ratiow; float h = pdata[3] * ratioh; int left = int(cx - 0.5 * w); int top = int(cy - 0.5 * h); confidences.push_back((float)maxClassScore); boxes.push_back(cv::Rect(left, top, (int)(w), (int)(h))); classIds.push_back(classIdx); } } rowInd++; pdata += numOut; } //执行non maximum suppression消除冗余重叠boxes std::vector indices; cv::dnn::NMSBoxes(boxes, confidences, yolov7Parameter.confidenceThreshold, yolov7Parameter.nmsThreshold, indices); for (size_t i = 0; i < indices.size(); ++i) { int idx = indices[i]; int classID=classIds[idx]; std::string className=classNames[classID]; float confidence=confidences[idx]; cv::Rect box = boxes[idx]; ResultOfDetection result; result.boundingBox=box; result.confidence=confidence;// confidence result.classID=classID; // label result.className=className; resultsOfDetection.push_back(result); } return SUCCESS; } }