// QRcode3Ddetection_test.cpp : 此文件包含 "main" 函数。程序执行将在此处开始并结束。 // #include #include #include #include #include #include "direct.h" #include #include "WD_QRcode3Ddetection_Export.h" #include #include typedef struct { int r; int g; int b; }SG_color; void vzReadLaserScanPointFromFile_plyTxt(const char* fileName, std::vector< SVzNL3DPoint>& scanData, bool removeZeros, bool exchangeXY) { std::ifstream inputFile(fileName); std::string linedata; if (inputFile.is_open() == false) return; while (std::getline(inputFile, linedata)) { if (linedata.empty()) continue; double X, Y, Z, tmp; sscanf_s(linedata.c_str(), "%lf %lf %lf %lf", &X, &Y, &Z, &tmp); if (true == removeZeros) { if (Z > 1e-4) { SVzNL3DPoint a_pt; if (true == exchangeXY) { a_pt.x = Y; //将扫描线调整为Y方向；扫描方向为X方向 a_pt.y = X; } else { a_pt.x = X; a_pt.y = Y; } a_pt.z = Z; scanData.push_back(a_pt); } } else { SVzNL3DPoint a_pt; if (true == exchangeXY) { a_pt.x = Y; //将扫描线调整为Y方向；扫描方向为X方向 a_pt.y = X; } else { a_pt.x = X; a_pt.y = Y; } a_pt.z = Z; scanData.push_back(a_pt); } } return; } typedef struct { int x; double y; double z; } WD_Encode3DPoint; void vzReadLaserScanPointFromFile_encodePlyTxt(const char* fileName, std::vector< WD_Encode3DPoint>& scanData) { std::ifstream inputFile(fileName); std::string linedata; if (inputFile.is_open() == false) return; while (std::getline(inputFile, linedata)) { if (linedata.empty()) continue; int X; double Y, Z, tmp; sscanf_s(linedata.c_str(), "%d,%lf,%lf", &X, &Y, &Z); WD_Encode3DPoint a_pt; a_pt.x = X; a_pt.y = Y; a_pt.z = Z; scanData.push_back(a_pt); } return; } void convertEncodePlyToVzData(std::vector< WD_Encode3DPoint>& scanData, std::vector>& scanLines, double stepping, bool toGrid) { int size = (int)scanData.size(); int preEnc = -1; std::vector a_line; int vldNum = 0; double lineX = 0; for (int i = 0; i < size; i++) { WD_Encode3DPoint a_ply = scanData[i]; if (a_ply.x != preEnc) //new line { if (vldNum > 0) { scanLines.push_back(a_line); a_line.clear(); } if (preEnc < 0) lineX = 0; else lineX += (double)(a_ply.x - preEnc) * stepping; preEnc = a_ply.x; vldNum = 0; } SVzNL3DPosition a_pt; a_pt.nPointIdx = vldNum; bool zeroPt = true; if ((a_ply.z > 29.0) && (a_ply.z < 34.0)) { a_pt.pt3D.x = lineX; a_pt.pt3D.y = a_ply.y; a_pt.pt3D.z = a_ply.z; zeroPt = false; } else { a_pt.pt3D.x = 0; a_pt.pt3D.y = 0; a_pt.pt3D.z = 0; } if (toGrid == true) { a_line.push_back(a_pt); vldNum++; } else { if (false == zeroPt) { a_line.push_back(a_pt); vldNum++; } } } } void _outputScanDataFile_vector(char* fileName, std::vector>& scanLines, bool removeZeros, int* headNullLines) { std::ofstream sw(fileName); int lineNum = scanLines.size(); if (lineNum == 0) return; sw << "LineNum:" << lineNum << std::endl; sw << "DataType: 0" << std::endl; sw << "ScanSpeed: 0" << std::endl; sw << "PointAdjust: 1" << std::endl; sw << "MaxTimeStamp: 0_0" << std::endl; int lineIdx = 0; int null_lines = 0; bool counterNull = true; for (int line = 0; line < lineNum; line++) { int linePtNum = scanLines[line].size(); if (linePtNum == 0) continue; if (true == removeZeros) { int vldPtNum = 0; for (int i = 0; i < linePtNum; i++) { if (scanLines[line][i].pt3D.z > 1e-4) vldPtNum++; } linePtNum = vldPtNum; } sw << "Line_" << lineIdx << "_0_" << linePtNum << std::endl; lineIdx++; bool isNull = true; for (int i = 0; i < linePtNum; i++) { SVzNL3DPoint* pt3D = &scanLines[line][i].pt3D; if ((pt3D->z > 1e-4) && (isNull == true)) isNull = false; if ((true == removeZeros) && (pt3D->z < 1e-4)) continue; float x = (float)pt3D->x; float y = (float)pt3D->y; float z = (float)pt3D->z; sw << "{ " << x << "," << y << "," << z << " }-"; sw << "{0,0}-{0,0}" << std::endl; } if (true == counterNull) { if (true == isNull) null_lines++; else counterNull = false; } } *headNullLines = null_lines; sw.close(); } void _outputScanPlyTxtFile_vector(char* fileName, std::vector>& scanLines, bool removeZeros, int* headNullLines) { std::ofstream sw(fileName); int lineNum = scanLines.size(); if (lineNum == 0) return; int null_lines = 0; bool counterNull = true; for (int line = 0; line < lineNum; line++) { int linePtNum = scanLines[line].size(); if (linePtNum == 0) continue; bool isNull = true; for (int i = 0; i < linePtNum; i++) { SVzNL3DPoint* pt3D = &scanLines[line][i].pt3D; if ((pt3D->z > 1e-4) && (isNull == true)) isNull = false; if ((true == removeZeros) && (pt3D->z < 1e-4)) continue; float x = (float)pt3D->x; float y = (float)pt3D->y; float z = (float)pt3D->z; sw << x << "," << y << "," << z<< std::endl; } if (true == counterNull) { if (true == isNull) null_lines++; else counterNull = false; } } *headNullLines = null_lines; sw.close(); } void _outputRGBDScanDataFile_RGBD( char* fileName, std::vector>& scanLines, std::vector< SVzNL3DPosition> objPoints) { int lineNum = scanLines.size(); std::ofstream sw(fileName); int realLines = lineNum; if (objPoints.size() > 0) realLines++; sw << "LineNum:" << realLines << std::endl; sw << "DataType: 0" << std::endl; sw << "ScanSpeed: 0" << std::endl; sw << "PointAdjust: 1" << std::endl; sw << "MaxTimeStamp: 0_0" << std::endl; int maxLineIndex = 0; int max_stamp = 0; SG_color rgb = { 0, 0, 0 }; SG_color objColor[8] = { {245,222,179},//淡黄色 {210,105, 30},//巧克力色 {240,230,140},//黄褐色 {135,206,235},//天蓝色 {250,235,215},//古董白 {189,252,201},//薄荷色 {221,160,221},//梅红色 {188,143,143},//玫瑰红色 }; int size = 1; int lineIdx = 0; for (int line = 0; line < lineNum; line++) { int linePtNum = scanLines[line].size(); if (linePtNum == 0) continue; sw << "Line_" << lineIdx << "_0_" << linePtNum << std::endl; lineIdx++; for (int i = 0; i < linePtNum; i++) { SVzNL3DPosition* pt3D = &scanLines[line][i]; int featureType = pt3D->nPointIdx; if (LINE_FEATURE_PEAK_TOP == featureType) { rgb = { 255, 97, 0 }; size = 5; } else { rgb = { 200, 200, 200 }; size = 1; } float x = (float)pt3D->pt3D.x; float y = (float)pt3D->pt3D.y; float z = (float)pt3D->pt3D.z; sw << "{" << x << "," << y << "," << z << "}-"; sw << "{0,0}-{0,0}-"; sw << "{" << rgb.r << "," << rgb.g << "," << rgb.b << "," << size << " }" << std::endl; } } if (objPoints.size() > 0) { int linePtNum = objPoints.size(); sw << "Line_" << lineNum << "_0_" << linePtNum+1 << std::endl; rgb = { 0, 0, 255 }; size = 25; for (int i = 0; i < linePtNum; i++) { float x = (float)objPoints[i].pt3D.x; float y = (float)objPoints[i].pt3D.y; float z = (float)objPoints[i].pt3D.z; sw << "{" << x << "," << y << "," << z << "}-"; sw << "{0,0}-{0,0}-"; sw << "{" << rgb.r << "," << rgb.g << "," << rgb.b << "," << size << " }" << std::endl; } float x = (float)objPoints[0].pt3D.x; float y = (float)objPoints[0].pt3D.y; float z = (float)objPoints[0].pt3D.z; sw << "{" << x << "," << y << "," << z << "}-"; sw << "{0,0}-{0,0}-"; sw << "{" << rgb.r << "," << rgb.g << "," << rgb.b << "," << size << " }" << std::endl; } sw.close(); } void _outputScanDataFile_ptr(char* fileName, SVzNL3DLaserLine* scanData, int lineNum) { std::ofstream sw(fileName); sw << "LineNum:" << lineNum << std::endl; sw << "DataType: 0" << std::endl; sw << "ScanSpeed: 0" << std::endl; sw << "PointAdjust: 1" << std::endl; sw << "MaxTimeStamp: 0_0" << std::endl; for (int line = 0; line < lineNum; line++) { sw << "Line_" << line << "_" << scanData[line].nTimeStamp << "_" << scanData[line].nPositionCnt << std::endl; for (int i = 0; i < scanData[line].nPositionCnt; i++) { SVzNL3DPosition* pt3D = &scanData[line].p3DPosition[i]; float x = (float)pt3D->pt3D.x; float y = (float)pt3D->pt3D.y; float z = (float)pt3D->pt3D.z; sw << "{" << x << "," << y << "," << z << "}-"; sw << "{0,0}-{0,0}" << std::endl; } } sw.close(); } #define DATA_VER_OLD 0 #define DATA_VER_NEW 1 #define DATA_VER_FROM_CUSTOM 2 #define VZ_LASER_LINE_PT_MAX_NUM 4096 SVzNL3DLaserLine* vzReadLaserScanPointFromFile_XYZ(const char* fileName, int* scanLineNum, float* scanV, int* dataCalib, int* scanMaxStamp, int* canClockUnit) { std::ifstream inputFile(fileName); std::string linedata; if (inputFile.is_open() == false) return NULL; SVzNL3DLaserLine* _scanLines = NULL; int lines = 0; int dataElements = 4; int firstIndex = -1; int dataFileVer = DATA_VER_OLD; std::getline(inputFile, linedata); //第一行 int lineNum = 0; if (0 == strncmp("LineNum:", linedata.c_str(), 8)) { dataFileVer = DATA_VER_NEW; sscanf_s(linedata.c_str(), "LineNum:%d", &lines); if (lines == 0) return NULL; lineNum = lines; _scanLines = (SVzNL3DLaserLine*)malloc(sizeof(SVzNL3DLaserLine) * (lineNum + 1)); memset(_scanLines, 0, sizeof(SVzNL3DLaserLine) * (lineNum + 1)); if (scanLineNum) *scanLineNum = lines; } else if (0 == strncmp("LineNum_", linedata.c_str(), 8)) { dataFileVer = DATA_VER_OLD; sscanf_s(linedata.c_str(), "LineNum_%d", &lines); if (lines == 0) return NULL; lineNum = lines; _scanLines = (SVzNL3DLaserLine*)malloc(sizeof(SVzNL3DLaserLine) * (lineNum + 1)); memset(_scanLines, 0, sizeof(SVzNL3DLaserLine) * (lineNum + 1)); if (scanLineNum) *scanLineNum = lines; } if (_scanLines == NULL) return NULL; int ptNum = 0; int lineIdx = -1; int ptIdx = 0; SVzNL3DPosition* p3DPoint = NULL; if (dataFileVer == DATA_VER_NEW) { while (getline(inputFile, linedata)) { if (0 == strncmp("ScanSpeed:", linedata.c_str(), 10)) { double lineV = 0; sscanf_s(linedata.c_str(), "ScanSpeed:%lf", &lineV); if (scanV) *scanV = (float)lineV; } else if (0 == strncmp("PointAdjust:", linedata.c_str(), 12)) { int ptAdjusted = 0; sscanf_s(linedata.c_str(), "PointAdjust:%d", &ptAdjusted); if (dataCalib) *dataCalib = ptAdjusted; } else if (0 == strncmp("MaxTimeStamp:", linedata.c_str(), 13)) { unsigned int maxTimeStamp = 0; unsigned int timePerStamp = 0; sscanf_s(linedata.c_str(), "MaxTimeStamp:%u_%u", &maxTimeStamp, &timePerStamp); if (scanMaxStamp) *scanMaxStamp = maxTimeStamp; if (canClockUnit) *canClockUnit = timePerStamp; } else if (0 == strncmp("Line_", linedata.c_str(), 5)) { int lineIndex; unsigned int timeStamp; sscanf_s(linedata.c_str(), "Line_%d_%u_%d", &lineIndex, &timeStamp, &ptNum); if (firstIndex < 0) firstIndex = lineIndex; lineIndex = lineIndex - firstIndex; if ((lineIndex < 0) || (lineIndex >= lines)) break; //new Line lineIdx++; if (ptNum > 0) { p3DPoint = (SVzNL3DPosition*)malloc(sizeof(SVzNL3DPosition) * ptNum); memset(p3DPoint, 0, sizeof(SVzNL3DPosition) * ptNum); } else p3DPoint = NULL; _scanLines[lineIdx].nPositionCnt = 0; _scanLines[lineIdx].nTimeStamp = timeStamp; _scanLines[lineIdx].p3DPosition = p3DPoint; } else if (0 == strncmp("{", linedata.c_str(), 1)) { float X, Y, Z; int imageY = 0; float leftX, leftY; float rightX, rightY; sscanf_s(linedata.c_str(), "{%f,%f,%f}-{%f,%f}-{%f,%f}", &X, &Y, &Z, &leftX, &leftY, &rightX, &rightY); int id = _scanLines[lineIdx].nPositionCnt; if (id < ptNum) { p3DPoint[id].pt3D.x = X; p3DPoint[id].pt3D.y = Y; p3DPoint[id].pt3D.z = Z; _scanLines[lineIdx].nPositionCnt = id + 1; } } } } else if (dataFileVer == DATA_VER_OLD) { while (getline(inputFile, linedata)) { if (0 == strncmp("DataElements_", linedata.c_str(), 13)) { sscanf_s(linedata.c_str(), "DataElements_%d", &dataElements); if ((dataElements != 3) && (dataElements != 4)) break; } if (0 == strncmp("LineV_", linedata.c_str(), 6)) { double lineV = 0; sscanf_s(linedata.c_str(), "LineV_%lf", &lineV); } else if (0 == strncmp("Line_", linedata.c_str(), 5)) { int lineIndex; unsigned int timeStamp; sscanf_s(linedata.c_str(), "Line_%d_%u", &lineIndex, &timeStamp); #if 0 if (scanLineListTail == NULL) firstIndex = lineIndex; #endif lineIndex = lineIndex - firstIndex; if ((lineIndex < 0) || (lineIndex >= lines)) break; //new Line //new Line lineIdx++; p3DPoint = (SVzNL3DPosition*)malloc(sizeof(SVzNL3DPosition) * VZ_LASER_LINE_PT_MAX_NUM); memset(p3DPoint, 0, sizeof(SVzNL3DPosition) * VZ_LASER_LINE_PT_MAX_NUM); _scanLines[lineIdx].nPositionCnt = 0; _scanLines[lineIdx].nTimeStamp = timeStamp; _scanLines[lineIdx].p3DPosition = p3DPoint; } else if (0 == strncmp("(", linedata.c_str(), 1)) { float X, Y, Z; int imageY = 0; if (dataElements == 4) sscanf_s(linedata.c_str(), "(%f,%f,%f,%d)", &X, &Y, &Z, &imageY); else sscanf_s(linedata.c_str(), "(%f,%f,%f)", &X, &Y, &Z); int id = _scanLines[lineIdx].nPositionCnt; if (id < VZ_LASER_LINE_PT_MAX_NUM) { p3DPoint[id].pt3D.x = X; p3DPoint[id].pt3D.y = Y; p3DPoint[id].pt3D.z = Z; _scanLines[lineIdx].nPositionCnt = id + 1; } } } } inputFile.close(); return _scanLines; } void vzReadLaserScanPointFromFile_XYZ_vector(const char* fileName, std::vector< SVzNL3DPoint>& scanData) { std::ifstream inputFile(fileName); std::string linedata; if (inputFile.is_open() == false) return; while (getline(inputFile, linedata)) { if (0 == strncmp("{", linedata.c_str(), 1)) { float X, Y, Z; int imageY = 0; float leftX, leftY; float rightX, rightY; sscanf_s(linedata.c_str(), "{%f,%f,%f}-{%f,%f}-{%f,%f}", &X, &Y, &Z, &leftX, &leftY, &rightX, &rightY); SVzNL3DPoint a_pt; a_pt.x = X; a_pt.y = Y; a_pt.z = Z; scanData.push_back(a_pt); } } inputFile.close(); return; } void _outputCalibPara(char* fileName, SSG_planeCalibPara calibPara) { std::ofstream sw(fileName); char dataStr[250]; //调平矩阵 sprintf_s(dataStr, 250, "%g, %g, %g", calibPara.planeCalib[0], calibPara.planeCalib[1], calibPara.planeCalib[2]); sw << dataStr << std::endl; sprintf_s(dataStr, 250, "%g, %g, %g", calibPara.planeCalib[3], calibPara.planeCalib[4], calibPara.planeCalib[5]); sw << dataStr << std::endl; sprintf_s(dataStr, 250, "%g, %g, %g", calibPara.planeCalib[6], calibPara.planeCalib[7], calibPara.planeCalib[8]); sw << dataStr << std::endl; //地面高度 sprintf_s(dataStr, 250, "%g", calibPara.planeHeight); sw << dataStr << std::endl; //反向旋转矩阵 sprintf_s(dataStr, 250, "%g, %g, %g", calibPara.invRMatrix[0], calibPara.invRMatrix[1], calibPara.invRMatrix[2]); sw << dataStr << std::endl; sprintf_s(dataStr, 250, "%g, %g, %g", calibPara.invRMatrix[3], calibPara.invRMatrix[4], calibPara.invRMatrix[5]); sw << dataStr << std::endl; sprintf_s(dataStr, 250, "%g, %g, %g", calibPara.invRMatrix[6], calibPara.invRMatrix[7], calibPara.invRMatrix[8]); sw << dataStr << std::endl; sw.close(); } SSG_planeCalibPara _readCalibPara(char* fileName) { //设置初始结果 double initCalib[9] = { 1.0, 0.0, 0.0, 0.0, 1.0, 0.0, 0.0, 0.0, 1.0 }; SSG_planeCalibPara planePara; for (int i = 0; i < 9; i++) planePara.planeCalib[i] = initCalib[i]; planePara.planeHeight = -1.0; for (int i = 0; i < 9; i++) planePara.invRMatrix[i] = initCalib[i]; std::ifstream inputFile(fileName); std::string linedata; if (inputFile.is_open() == false) return planePara; //调平矩阵 std::getline(inputFile, linedata); sscanf_s(linedata.c_str(), "%lf, %lf, %lf", &planePara.planeCalib[0], &planePara.planeCalib[1], &planePara.planeCalib[2]); std::getline(inputFile, linedata); sscanf_s(linedata.c_str(), "%lf, %lf, %lf", &planePara.planeCalib[3], &planePara.planeCalib[4], &planePara.planeCalib[5]); std::getline(inputFile, linedata); sscanf_s(linedata.c_str(), "%lf, %lf, %lf", &planePara.planeCalib[6], &planePara.planeCalib[7], &planePara.planeCalib[8]); //地面高度 std::getline(inputFile, linedata); sscanf_s(linedata.c_str(), "%lf", &planePara.planeHeight); //反向旋转矩阵 std::getline(inputFile, linedata); sscanf_s(linedata.c_str(), "%lf, %lf, %lf", &planePara.invRMatrix[0], &planePara.invRMatrix[1], &planePara.invRMatrix[2]); std::getline(inputFile, linedata); sscanf_s(linedata.c_str(), "%lf, %lf, %lf", &planePara.invRMatrix[3], &planePara.invRMatrix[4], &planePara.invRMatrix[5]); std::getline(inputFile, linedata); sscanf_s(linedata.c_str(), "%lf, %lf, %lf", &planePara.invRMatrix[6], &planePara.invRMatrix[7], &planePara.invRMatrix[8]); inputFile.close(); return planePara; } void _getRoiClouds( std::vector< std::vector>& scanLines, int startLine, int endLine, int startPtIdx, int endPtIdx, std::vector< std::vector>& roiScanLines) { for (int i = startLine; i < endLine; i++) { if (i >= scanLines.size()) break; std::vector cut_line; std::vector& a_line = scanLines[i]; for (int j = startPtIdx; j < endPtIdx; j++) { SVzNL3DPosition a_pt; if (j >= a_line.size()) { a_pt.nPointIdx = 0; a_pt.pt3D = { 0,0,0 }; } else a_pt = a_line[j]; cut_line.push_back(a_pt); } roiScanLines.push_back(cut_line); } return; } #define CONVERT_TO_GRID 1 #define TEST_COMPUTE_CALIB_PARA 0 #define TEST_COMPUTE_QRCODE_IMG 0 #define TEST_GROUP 2 int main() { const char* dataPath[TEST_GROUP] = { "F:\\ShangGu\\项目\\国铭铸管\\二维码\\", //0 "F:\\ShangGu\\项目\\国铭铸管\\字符\\" //1 }; SVzNLRange fileIdx[TEST_GROUP] = { {3,3}, {1,8} }; #if CONVERT_TO_GRID int convertGrp = 1; for (int fidx = fileIdx[convertGrp].nMin; fidx <= fileIdx[convertGrp].nMax; fidx++) { char _scan_file[256]; sprintf_s(_scan_file, "%sdata%d.txt", dataPath[convertGrp], fidx); std::vector< WD_Encode3DPoint> scanPly; vzReadLaserScanPointFromFile_encodePlyTxt(_scan_file, scanPly); double stepping = 0.0625; std::vector> scanData; std::vector> gridScanData; bool toGrid = false; convertEncodePlyToVzData(scanPly, scanData, stepping, toGrid); toGrid = true; convertEncodePlyToVzData(scanPly, gridScanData, stepping, toGrid); //将数据恢复为按扫描线存储格式 sprintf_s(_scan_file, "%sscanDataPlyTxt_%d.txt", dataPath[convertGrp], fidx); int headNullLines = 0; _outputScanPlyTxtFile_vector(_scan_file, scanData, false, &headNullLines); #if 0 sprintf_s(_scan_file, "%svzScanData_%d.txt", dataPath[convertGrp], fidx); int headNullLines = 0; _outputScanDataFile_vector(_scan_file, scanData, false, &headNullLines); sprintf_s(_scan_file, "%svzScanData_grid_%d.txt", dataPath[convertGrp], fidx); _outputScanDataFile_vector(_scan_file, gridScanData, false, &headNullLines); printf("%s: head null lines = %d\n", _scan_file, headNullLines); #endif } #endif #if TEST_COMPUTE_CALIB_PARA char _calib_datafile[256]; sprintf_s(_calib_datafile, "F:\\ShangGu\\项目\\工件端部圆点二维码\\LaserLine3_grid.txt"); int lineNum = 0; float lineV = 0.0f; int dataCalib = 0; int maxTimeStamp = 0; int clockPerSecond = 0; SVzNL3DLaserLine* laser3DPoints = vzReadLaserScanPointFromFile_XYZ(_calib_datafile, &lineNum, &lineV, &dataCalib, &maxTimeStamp, &clockPerSecond); if (laser3DPoints) { SSG_planeCalibPara calibPara = wd_getBaseCalibPara( laser3DPoints, lineNum); //结果进行验证 for (int i = 0; i < lineNum; i++) { if (i == 14) int kkk = 1; //行处理 //调平，去除地面 wd_lineDataR(&laser3DPoints[i], calibPara.planeCalib, -1);// calibPara.planeHeight); } // char calibFile[250]; sprintf_s(calibFile, "F:\\ShangGu\\项目\\工件端部圆点二维码\\ground_calib_para.txt"); _outputCalibPara(calibFile, calibPara); char _out_file[256]; sprintf_s(_out_file, "F:\\ShangGu\\项目\\工件端部圆点二维码\\LaserLine3_calib_data.txt"); _outputScanDataFile_ptr(_out_file, laser3DPoints, lineNum); printf("%s: calib done!\n", _calib_datafile); } #endif #if TEST_COMPUTE_QRCODE_IMG for (int grp = 0; grp <= 0; grp++) { int cloud_rows = 4200; int cloud_cols = 2160; SSG_planeCalibPara poseCalibPara; //初始化成单位阵 poseCalibPara.planeCalib[0] = 1.0; poseCalibPara.planeCalib[1] = 0.0; poseCalibPara.planeCalib[2] = 0.0; poseCalibPara.planeCalib[3] = 0.0; poseCalibPara.planeCalib[4] = 1.0; poseCalibPara.planeCalib[5] = 0.0; poseCalibPara.planeCalib[6] = 0.0; poseCalibPara.planeCalib[7] = 0.0; poseCalibPara.planeCalib[8] = 1.0; poseCalibPara.planeHeight = -1.0; for (int i = 0; i < 9; i++) poseCalibPara.invRMatrix[i] = poseCalibPara.planeCalib[i]; char calibFile[250]; sprintf_s(calibFile, "F:\\ShangGu\\项目\\工件端部圆点二维码\\ground_calib_para.txt"); poseCalibPara = _readCalibPara(calibFile); for (int fidx = fileIdx[grp].nMin; fidx <= fileIdx[grp].nMax; fidx++) { //fidx = 1; char _scan_file[256]; sprintf_s(_scan_file, "%s%d_Cloud.txt", dataPath[grp], fidx); std::vector< SVzNL3DPoint> scanData; bool removeZeros = false; bool exchangeXY = true; if (fidx < 3) { cloud_cols = 1; //单行测试文件 exchangeXY = false; } else { cloud_cols = 2160; //单行测试文件 exchangeXY = true; } if (fidx == 2) { vzReadLaserScanPointFromFile_XYZ_vector(_scan_file, scanData); cloud_cols = 1100; cloud_rows = 1300; if (scanData.size() != (cloud_rows * cloud_cols)) continue; } else { vzReadLaserScanPointFromFile_plyTxt(_scan_file, scanData, removeZeros, exchangeXY); if (scanData.size() != (cloud_rows * cloud_cols)) continue; } //将数据恢复为按扫描线存储格式 std::vector< std::vector> scanLines; wd_getScanLines(scanData, scanLines, cloud_rows); #if 0 //点云裁剪 std::vector< std::vector> roiScanLines; _getRoiClouds(scanLines, 700, 1800, 400, 1700, roiScanLines); sprintf_s(_scan_file, "%sLaserLine4_grid.txt", dataPath[grp]); int headNullLines = 0; _outputScanDataFile_vector(_scan_file, roiScanLines, false, &headNullLines); #endif #if 0 sprintf_s(_scan_file, "%sLaserLine%d_grid.txt", dataPath[grp], fidx); int headNullLines = 0; _outputScanDataFile_vector(_scan_file, scanLines, false, &headNullLines); printf("%s: head null lines = %d\n", _scan_file, headNullLines); #endif WD_QRcodeParam qrcode_param; qrcode_param.rows = 14; qrcode_param.cols = 14; qrcode_param.row_space = 30.0 / 14; qrcode_param.col_space = 30.0 / 14; qrcode_param.pointHoleDepth = 1.0; qrcode_param.pointHoleR = 0.6; long t1 = GetTickCount64();//统计时间 for (int i = 0, i_max= scanLines.size(); i < i_max; i++) { if (i == 14) int kkk = 1; //行处理 //调平，去除地面 wd_lineDataR(scanLines[i], poseCalibPara.planeCalib, -1); } // #if 0 sprintf_s(_scan_file, "%sresult\\LaserLine%d_calib_data.txt", dataPath[grp], fidx); int headNulls = 0; _outputScanDataFile_vector(_scan_file, scanLines, true, &headNulls); #endif cv::Mat dmCodeImg; std::vector< SVzNL3DPosition> objPoints; wd_QRcode3Ddetection( scanLines, qrcode_param, objPoints, dmCodeImg); long t2 = GetTickCount64(); printf("%s: %d(ms)!\n", _scan_file, (int)(t2 - t1)); //输出测试结果 sprintf_s(_scan_file, "%sresult\\LaserLine%d_result.txt", dataPath[grp], fidx); _outputRGBDScanDataFile_RGBD(_scan_file, scanLines, objPoints); if (!dmCodeImg.empty()) { sprintf_s(_scan_file, "%sresult\\LaserLine%d_img.png", dataPath[grp], fidx); cv::Mat normDmCodeImg; cv::normalize(dmCodeImg, normDmCodeImg, 0, 255, cv::NORM_MINMAX, CV_8U); cv::imwrite(_scan_file, normDmCodeImg); } } } #endif } // 运行程序: Ctrl + F5 或调试 >“开始执行(不调试)”菜单 // 调试程序: F5 或调试 >“开始调试”菜单 // 入门使用技巧: // 1. 使用解决方案资源管理器窗口添加/管理文件 // 2. 使用团队资源管理器窗口连接到源代码管理 // 3. 使用输出窗口查看生成输出和其他消息 // 4. 使用错误列表窗口查看错误 // 5. 转到“项目”>“添加新项”以创建新的代码文件，或转到“项目”>“添加现有项”以将现有代码文件添加到项目 // 6. 将来，若要再次打开此项目，请转到“文件”>“打开”>“项目”并选择 .sln 文件