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531 lines
20 KiB
C++
531 lines
20 KiB
C++
// This file is part of OpenCV project.
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// It is subject to the license terms in the LICENSE file found in the top-level directory
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// of this distribution and at http://opencv.org/license.html.
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#include "frameProcessor.hpp"
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#include "rotationConverters.hpp"
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#include <opencv2/calib3d.hpp>
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#include <opencv2/imgproc.hpp>
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#include <opencv2/highgui.hpp>
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#include <vector>
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#include <string>
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#include <algorithm>
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#include <limits>
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using namespace calib;
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#define VIDEO_TEXT_SIZE 4
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#define POINT_SIZE 5
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static cv::SimpleBlobDetector::Params getDetectorParams()
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{
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cv::SimpleBlobDetector::Params detectorParams;
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detectorParams.thresholdStep = 40;
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detectorParams.minThreshold = 20;
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detectorParams.maxThreshold = 500;
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detectorParams.minRepeatability = 2;
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detectorParams.minDistBetweenBlobs = 5;
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detectorParams.filterByColor = true;
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detectorParams.blobColor = 0;
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detectorParams.filterByArea = true;
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detectorParams.minArea = 5;
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detectorParams.maxArea = 5000;
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detectorParams.filterByCircularity = false;
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detectorParams.minCircularity = 0.8f;
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detectorParams.maxCircularity = std::numeric_limits<float>::max();
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detectorParams.filterByInertia = true;
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detectorParams.minInertiaRatio = 0.1f;
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detectorParams.maxInertiaRatio = std::numeric_limits<float>::max();
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detectorParams.filterByConvexity = true;
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detectorParams.minConvexity = 0.8f;
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detectorParams.maxConvexity = std::numeric_limits<float>::max();
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return detectorParams;
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}
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FrameProcessor::~FrameProcessor()
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{
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}
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bool CalibProcessor::detectAndParseChessboard(const cv::Mat &frame)
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{
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int chessBoardFlags = cv::CALIB_CB_ADAPTIVE_THRESH | cv::CALIB_CB_NORMALIZE_IMAGE | cv::CALIB_CB_FAST_CHECK;
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bool isTemplateFound = cv::findChessboardCorners(frame, mBoardSize, mCurrentImagePoints, chessBoardFlags);
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if (isTemplateFound) {
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cv::Mat viewGray;
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cv::cvtColor(frame, viewGray, cv::COLOR_BGR2GRAY);
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cv::cornerSubPix(viewGray, mCurrentImagePoints, cv::Size(11,11),
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cv::Size(-1,-1), cv::TermCriteria( cv::TermCriteria::EPS+cv::TermCriteria::COUNT, 30, 0.1 ));
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cv::drawChessboardCorners(frame, mBoardSize, cv::Mat(mCurrentImagePoints), isTemplateFound);
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mTemplateLocations.insert(mTemplateLocations.begin(), mCurrentImagePoints[0]);
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}
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return isTemplateFound;
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}
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bool CalibProcessor::detectAndParseChAruco(const cv::Mat &frame)
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{
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#ifdef HAVE_OPENCV_ARUCO
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cv::Ptr<cv::aruco::Board> board = mCharucoBoard.staticCast<cv::aruco::Board>();
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std::vector<std::vector<cv::Point2f> > corners, rejected;
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std::vector<int> ids;
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cv::aruco::detectMarkers(frame, mArucoDictionary, corners, ids, cv::aruco::DetectorParameters::create(), rejected);
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cv::aruco::refineDetectedMarkers(frame, board, corners, ids, rejected);
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cv::Mat currentCharucoCorners, currentCharucoIds;
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if(ids.size() > 0)
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cv::aruco::interpolateCornersCharuco(corners, ids, frame, mCharucoBoard, currentCharucoCorners,
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currentCharucoIds);
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if(ids.size() > 0) cv::aruco::drawDetectedMarkers(frame, corners);
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if(currentCharucoCorners.total() > 3) {
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float centerX = 0, centerY = 0;
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for (int i = 0; i < currentCharucoCorners.size[0]; i++) {
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centerX += currentCharucoCorners.at<float>(i, 0);
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centerY += currentCharucoCorners.at<float>(i, 1);
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}
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centerX /= currentCharucoCorners.size[0];
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centerY /= currentCharucoCorners.size[0];
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mTemplateLocations.insert(mTemplateLocations.begin(), cv::Point2f(centerX, centerY));
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cv::aruco::drawDetectedCornersCharuco(frame, currentCharucoCorners, currentCharucoIds);
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mCurrentCharucoCorners = currentCharucoCorners;
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mCurrentCharucoIds = currentCharucoIds;
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return true;
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}
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#else
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CV_UNUSED(frame);
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#endif
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return false;
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}
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bool CalibProcessor::detectAndParseACircles(const cv::Mat &frame)
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{
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bool isTemplateFound = findCirclesGrid(frame, mBoardSize, mCurrentImagePoints, cv::CALIB_CB_ASYMMETRIC_GRID, mBlobDetectorPtr);
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if(isTemplateFound) {
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mTemplateLocations.insert(mTemplateLocations.begin(), mCurrentImagePoints[0]);
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cv::drawChessboardCorners(frame, mBoardSize, cv::Mat(mCurrentImagePoints), isTemplateFound);
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}
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return isTemplateFound;
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}
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bool CalibProcessor::detectAndParseDualACircles(const cv::Mat &frame)
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{
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std::vector<cv::Point2f> blackPointbuf;
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cv::Mat invertedView;
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cv::bitwise_not(frame, invertedView);
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bool isWhiteGridFound = cv::findCirclesGrid(frame, mBoardSize, mCurrentImagePoints, cv::CALIB_CB_ASYMMETRIC_GRID, mBlobDetectorPtr);
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if(!isWhiteGridFound)
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return false;
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bool isBlackGridFound = cv::findCirclesGrid(invertedView, mBoardSize, blackPointbuf, cv::CALIB_CB_ASYMMETRIC_GRID, mBlobDetectorPtr);
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if(!isBlackGridFound)
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{
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mCurrentImagePoints.clear();
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return false;
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}
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cv::drawChessboardCorners(frame, mBoardSize, cv::Mat(mCurrentImagePoints), isWhiteGridFound);
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cv::drawChessboardCorners(frame, mBoardSize, cv::Mat(blackPointbuf), isBlackGridFound);
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mCurrentImagePoints.insert(mCurrentImagePoints.end(), blackPointbuf.begin(), blackPointbuf.end());
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mTemplateLocations.insert(mTemplateLocations.begin(), mCurrentImagePoints[0]);
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return true;
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}
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void CalibProcessor::saveFrameData()
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{
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std::vector<cv::Point3f> objectPoints;
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switch(mBoardType)
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{
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case Chessboard:
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objectPoints.reserve(mBoardSize.height*mBoardSize.width);
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for( int i = 0; i < mBoardSize.height; ++i )
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for( int j = 0; j < mBoardSize.width; ++j )
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objectPoints.push_back(cv::Point3f(j*mSquareSize, i*mSquareSize, 0));
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mCalibData->imagePoints.push_back(mCurrentImagePoints);
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mCalibData->objectPoints.push_back(objectPoints);
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break;
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case chAruco:
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mCalibData->allCharucoCorners.push_back(mCurrentCharucoCorners);
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mCalibData->allCharucoIds.push_back(mCurrentCharucoIds);
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break;
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case AcirclesGrid:
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objectPoints.reserve(mBoardSize.height*mBoardSize.width);
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for( int i = 0; i < mBoardSize.height; i++ )
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for( int j = 0; j < mBoardSize.width; j++ )
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objectPoints.push_back(cv::Point3f((2*j + i % 2)*mSquareSize, i*mSquareSize, 0));
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mCalibData->imagePoints.push_back(mCurrentImagePoints);
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mCalibData->objectPoints.push_back(objectPoints);
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break;
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case DoubleAcirclesGrid:
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{
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float gridCenterX = (2*((float)mBoardSize.width - 1) + 1)*mSquareSize + mTemplDist / 2;
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float gridCenterY = (mBoardSize.height - 1)*mSquareSize / 2;
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objectPoints.reserve(2*mBoardSize.height*mBoardSize.width);
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//white part
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for( int i = 0; i < mBoardSize.height; i++ )
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for( int j = 0; j < mBoardSize.width; j++ )
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objectPoints.push_back(
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cv::Point3f(-float((2*j + i % 2)*mSquareSize + mTemplDist +
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(2*(mBoardSize.width - 1) + 1)*mSquareSize - gridCenterX),
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-float(i*mSquareSize) - gridCenterY,
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0));
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//black part
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for( int i = 0; i < mBoardSize.height; i++ )
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for( int j = 0; j < mBoardSize.width; j++ )
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objectPoints.push_back(cv::Point3f(-float((2*j + i % 2)*mSquareSize - gridCenterX),
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-float(i*mSquareSize) - gridCenterY, 0));
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mCalibData->imagePoints.push_back(mCurrentImagePoints);
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mCalibData->objectPoints.push_back(objectPoints);
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}
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break;
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}
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}
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void CalibProcessor::showCaptureMessage(const cv::Mat& frame, const std::string &message)
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{
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cv::Point textOrigin(100, 100);
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double textSize = VIDEO_TEXT_SIZE * frame.cols / (double) IMAGE_MAX_WIDTH;
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cv::bitwise_not(frame, frame);
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cv::putText(frame, message, textOrigin, 1, textSize, cv::Scalar(0,0,255), 2, cv::LINE_AA);
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cv::imshow(mainWindowName, frame);
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cv::waitKey(300);
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}
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bool CalibProcessor::checkLastFrame()
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{
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bool isFrameBad = false;
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cv::Mat tmpCamMatrix;
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const double badAngleThresh = 40;
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if(!mCalibData->cameraMatrix.total()) {
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tmpCamMatrix = cv::Mat::eye(3, 3, CV_64F);
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tmpCamMatrix.at<double>(0,0) = 20000;
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tmpCamMatrix.at<double>(1,1) = 20000;
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tmpCamMatrix.at<double>(0,2) = mCalibData->imageSize.height/2;
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tmpCamMatrix.at<double>(1,2) = mCalibData->imageSize.width/2;
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}
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else
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mCalibData->cameraMatrix.copyTo(tmpCamMatrix);
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if(mBoardType != chAruco) {
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cv::Mat r, t, angles;
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cv::solvePnP(mCalibData->objectPoints.back(), mCurrentImagePoints, tmpCamMatrix, mCalibData->distCoeffs, r, t);
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RodriguesToEuler(r, angles, CALIB_DEGREES);
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if(fabs(angles.at<double>(0)) > badAngleThresh || fabs(angles.at<double>(1)) > badAngleThresh) {
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mCalibData->objectPoints.pop_back();
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mCalibData->imagePoints.pop_back();
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isFrameBad = true;
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}
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}
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else {
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#ifdef HAVE_OPENCV_ARUCO
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cv::Mat r, t, angles;
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std::vector<cv::Point3f> allObjPoints;
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allObjPoints.reserve(mCurrentCharucoIds.total());
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for(size_t i = 0; i < mCurrentCharucoIds.total(); i++) {
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int pointID = mCurrentCharucoIds.at<int>((int)i);
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CV_Assert(pointID >= 0 && pointID < (int)mCharucoBoard->chessboardCorners.size());
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allObjPoints.push_back(mCharucoBoard->chessboardCorners[pointID]);
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}
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cv::solvePnP(allObjPoints, mCurrentCharucoCorners, tmpCamMatrix, mCalibData->distCoeffs, r, t);
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RodriguesToEuler(r, angles, CALIB_DEGREES);
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if(180.0 - fabs(angles.at<double>(0)) > badAngleThresh || fabs(angles.at<double>(1)) > badAngleThresh) {
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isFrameBad = true;
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mCalibData->allCharucoCorners.pop_back();
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mCalibData->allCharucoIds.pop_back();
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}
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#endif
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}
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return isFrameBad;
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}
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CalibProcessor::CalibProcessor(cv::Ptr<calibrationData> data, captureParameters &capParams) :
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mCalibData(data), mBoardType(capParams.board), mBoardSize(capParams.boardSize)
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{
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mCapuredFrames = 0;
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mNeededFramesNum = capParams.calibrationStep;
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mDelayBetweenCaptures = static_cast<int>(capParams.captureDelay * capParams.fps);
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mMaxTemplateOffset = std::sqrt(static_cast<float>(mCalibData->imageSize.height * mCalibData->imageSize.height) +
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static_cast<float>(mCalibData->imageSize.width * mCalibData->imageSize.width)) / 20.0;
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mSquareSize = capParams.squareSize;
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mTemplDist = capParams.templDst;
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switch(mBoardType)
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{
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case chAruco:
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#ifdef HAVE_OPENCV_ARUCO
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mArucoDictionary = cv::aruco::getPredefinedDictionary(
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cv::aruco::PREDEFINED_DICTIONARY_NAME(capParams.charucoDictName));
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mCharucoBoard = cv::aruco::CharucoBoard::create(mBoardSize.width, mBoardSize.height, capParams.charucoSquareLenght,
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capParams.charucoMarkerSize, mArucoDictionary);
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#endif
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break;
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case AcirclesGrid:
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mBlobDetectorPtr = cv::SimpleBlobDetector::create();
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break;
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case DoubleAcirclesGrid:
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mBlobDetectorPtr = cv::SimpleBlobDetector::create(getDetectorParams());
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break;
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case Chessboard:
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break;
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}
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}
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cv::Mat CalibProcessor::processFrame(const cv::Mat &frame)
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{
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cv::Mat frameCopy;
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frame.copyTo(frameCopy);
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bool isTemplateFound = false;
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mCurrentImagePoints.clear();
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switch(mBoardType)
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{
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case Chessboard:
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isTemplateFound = detectAndParseChessboard(frameCopy);
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break;
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case chAruco:
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isTemplateFound = detectAndParseChAruco(frameCopy);
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break;
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case AcirclesGrid:
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isTemplateFound = detectAndParseACircles(frameCopy);
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break;
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case DoubleAcirclesGrid:
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isTemplateFound = detectAndParseDualACircles(frameCopy);
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break;
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}
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if(mTemplateLocations.size() > mDelayBetweenCaptures)
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mTemplateLocations.pop_back();
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if(mTemplateLocations.size() == mDelayBetweenCaptures && isTemplateFound) {
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if(cv::norm(mTemplateLocations.front() - mTemplateLocations.back()) < mMaxTemplateOffset) {
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saveFrameData();
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bool isFrameBad = checkLastFrame();
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if (!isFrameBad) {
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std::string displayMessage = cv::format("Frame # %zu captured", std::max(mCalibData->imagePoints.size(),
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mCalibData->allCharucoCorners.size()));
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if(!showOverlayMessage(displayMessage))
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showCaptureMessage(frame, displayMessage);
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mCapuredFrames++;
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}
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else {
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std::string displayMessage = "Frame rejected";
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if(!showOverlayMessage(displayMessage))
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showCaptureMessage(frame, displayMessage);
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}
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mTemplateLocations.clear();
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mTemplateLocations.reserve(mDelayBetweenCaptures);
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}
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}
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return frameCopy;
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}
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bool CalibProcessor::isProcessed() const
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{
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if(mCapuredFrames < mNeededFramesNum)
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return false;
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else
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return true;
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}
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void CalibProcessor::resetState()
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{
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mCapuredFrames = 0;
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mTemplateLocations.clear();
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}
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CalibProcessor::~CalibProcessor()
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{
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}
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////////////////////////////////////////////
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void ShowProcessor::drawBoard(cv::Mat &img, cv::InputArray points)
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{
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cv::Mat tmpView = cv::Mat::zeros(img.rows, img.cols, CV_8UC3);
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std::vector<cv::Point2f> templateHull;
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std::vector<cv::Point> poly;
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cv::convexHull(points, templateHull);
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poly.resize(templateHull.size());
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for(size_t i=0; i<templateHull.size();i++)
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poly[i] = cv::Point((int)(templateHull[i].x*mGridViewScale), (int)(templateHull[i].y*mGridViewScale));
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cv::fillConvexPoly(tmpView, poly, cv::Scalar(0, 255, 0), cv::LINE_AA);
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cv::addWeighted(tmpView, .2, img, 1, 0, img);
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}
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void ShowProcessor::drawGridPoints(const cv::Mat &frame)
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{
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if(mBoardType != chAruco)
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for(std::vector<std::vector<cv::Point2f> >::iterator it = mCalibdata->imagePoints.begin(); it != mCalibdata->imagePoints.end(); ++it)
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for(std::vector<cv::Point2f>::iterator pointIt = (*it).begin(); pointIt != (*it).end(); ++pointIt)
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cv::circle(frame, *pointIt, POINT_SIZE, cv::Scalar(0, 255, 0), 1, cv::LINE_AA);
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else
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for(std::vector<cv::Mat>::iterator it = mCalibdata->allCharucoCorners.begin(); it != mCalibdata->allCharucoCorners.end(); ++it)
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for(int i = 0; i < (*it).size[0]; i++)
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cv::circle(frame, cv::Point((int)(*it).at<float>(i, 0), (int)(*it).at<float>(i, 1)),
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POINT_SIZE, cv::Scalar(0, 255, 0), 1, cv::LINE_AA);
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}
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ShowProcessor::ShowProcessor(cv::Ptr<calibrationData> data, cv::Ptr<calibController> controller, TemplateType board) :
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mCalibdata(data), mController(controller), mBoardType(board)
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{
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mNeedUndistort = true;
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mVisMode = Grid;
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mGridViewScale = 0.5;
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mTextSize = VIDEO_TEXT_SIZE;
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}
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cv::Mat ShowProcessor::processFrame(const cv::Mat &frame)
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{
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if (!mCalibdata->cameraMatrix.empty() && !mCalibdata->distCoeffs.empty())
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{
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mTextSize = VIDEO_TEXT_SIZE * (double) frame.cols / IMAGE_MAX_WIDTH;
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cv::Scalar textColor = cv::Scalar(0,0,255);
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cv::Mat frameCopy;
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if (mNeedUndistort && mController->getFramesNumberState()) {
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if(mVisMode == Grid)
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drawGridPoints(frame);
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cv::remap(frame, frameCopy, mCalibdata->undistMap1, mCalibdata->undistMap2, cv::INTER_LINEAR);
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int baseLine = 100;
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cv::Size textSize = cv::getTextSize("Undistorted view", 1, mTextSize, 2, &baseLine);
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cv::Point textOrigin(baseLine, frame.rows - (int)(2.5*textSize.height));
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cv::putText(frameCopy, "Undistorted view", textOrigin, 1, mTextSize, textColor, 2, cv::LINE_AA);
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}
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else {
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frame.copyTo(frameCopy);
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if(mVisMode == Grid)
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drawGridPoints(frameCopy);
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}
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std::string displayMessage;
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if(mCalibdata->stdDeviations.at<double>(0) == 0)
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displayMessage = cv::format("F = %d RMS = %.3f", (int)mCalibdata->cameraMatrix.at<double>(0,0), mCalibdata->totalAvgErr);
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else
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displayMessage = cv::format("Fx = %d Fy = %d RMS = %.3f", (int)mCalibdata->cameraMatrix.at<double>(0,0),
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(int)mCalibdata->cameraMatrix.at<double>(1,1), mCalibdata->totalAvgErr);
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if(mController->getRMSState() && mController->getFramesNumberState())
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displayMessage.append(" OK");
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int baseLine = 100;
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cv::Size textSize = cv::getTextSize(displayMessage, 1, mTextSize - 1, 2, &baseLine);
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cv::Point textOrigin = cv::Point(baseLine, 2*textSize.height);
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cv::putText(frameCopy, displayMessage, textOrigin, 1, mTextSize - 1, textColor, 2, cv::LINE_AA);
|
|
|
|
if(mCalibdata->stdDeviations.at<double>(0) == 0)
|
|
displayMessage = cv::format("DF = %.2f", mCalibdata->stdDeviations.at<double>(1)*sigmaMult);
|
|
else
|
|
displayMessage = cv::format("DFx = %.2f DFy = %.2f", mCalibdata->stdDeviations.at<double>(0)*sigmaMult,
|
|
mCalibdata->stdDeviations.at<double>(1)*sigmaMult);
|
|
if(mController->getConfidenceIntrervalsState() && mController->getFramesNumberState())
|
|
displayMessage.append(" OK");
|
|
cv::putText(frameCopy, displayMessage, cv::Point(baseLine, 4*textSize.height), 1, mTextSize - 1, textColor, 2, cv::LINE_AA);
|
|
|
|
if(mController->getCommonCalibrationState()) {
|
|
displayMessage = cv::format("Calibration is done");
|
|
cv::putText(frameCopy, displayMessage, cv::Point(baseLine, 6*textSize.height), 1, mTextSize - 1, textColor, 2, cv::LINE_AA);
|
|
}
|
|
int calibFlags = mController->getNewFlags();
|
|
displayMessage = "";
|
|
if(!(calibFlags & cv::CALIB_FIX_ASPECT_RATIO))
|
|
displayMessage.append(cv::format("AR=%.3f ", mCalibdata->cameraMatrix.at<double>(0,0)/mCalibdata->cameraMatrix.at<double>(1,1)));
|
|
if(calibFlags & cv::CALIB_ZERO_TANGENT_DIST)
|
|
displayMessage.append("TD=0 ");
|
|
displayMessage.append(cv::format("K1=%.2f K2=%.2f K3=%.2f", mCalibdata->distCoeffs.at<double>(0), mCalibdata->distCoeffs.at<double>(1),
|
|
mCalibdata->distCoeffs.at<double>(4)));
|
|
cv::putText(frameCopy, displayMessage, cv::Point(baseLine, frameCopy.rows - (int)(1.5*textSize.height)),
|
|
1, mTextSize - 1, textColor, 2, cv::LINE_AA);
|
|
return frameCopy;
|
|
}
|
|
|
|
return frame;
|
|
}
|
|
|
|
bool ShowProcessor::isProcessed() const
|
|
{
|
|
return false;
|
|
}
|
|
|
|
void ShowProcessor::resetState()
|
|
{
|
|
|
|
}
|
|
|
|
void ShowProcessor::setVisualizationMode(visualisationMode mode)
|
|
{
|
|
mVisMode = mode;
|
|
}
|
|
|
|
void ShowProcessor::switchVisualizationMode()
|
|
{
|
|
if(mVisMode == Grid) {
|
|
mVisMode = Window;
|
|
updateBoardsView();
|
|
}
|
|
else {
|
|
mVisMode = Grid;
|
|
cv::destroyWindow(gridWindowName);
|
|
}
|
|
}
|
|
|
|
void ShowProcessor::clearBoardsView()
|
|
{
|
|
cv::imshow(gridWindowName, cv::Mat());
|
|
}
|
|
|
|
void ShowProcessor::updateBoardsView()
|
|
{
|
|
if(mVisMode == Window) {
|
|
cv::Size originSize = mCalibdata->imageSize;
|
|
cv::Mat altGridView = cv::Mat::zeros((int)(originSize.height*mGridViewScale), (int)(originSize.width*mGridViewScale), CV_8UC3);
|
|
if(mBoardType != chAruco)
|
|
for(std::vector<std::vector<cv::Point2f> >::iterator it = mCalibdata->imagePoints.begin(); it != mCalibdata->imagePoints.end(); ++it)
|
|
if(mBoardType != DoubleAcirclesGrid)
|
|
drawBoard(altGridView, *it);
|
|
else {
|
|
size_t pointsNum = (*it).size()/2;
|
|
std::vector<cv::Point2f> points(pointsNum);
|
|
std::copy((*it).begin(), (*it).begin() + pointsNum, points.begin());
|
|
drawBoard(altGridView, points);
|
|
std::copy((*it).begin() + pointsNum, (*it).begin() + 2*pointsNum, points.begin());
|
|
drawBoard(altGridView, points);
|
|
}
|
|
else
|
|
for(std::vector<cv::Mat>::iterator it = mCalibdata->allCharucoCorners.begin(); it != mCalibdata->allCharucoCorners.end(); ++it)
|
|
drawBoard(altGridView, *it);
|
|
cv::imshow(gridWindowName, altGridView);
|
|
}
|
|
}
|
|
|
|
void ShowProcessor::switchUndistort()
|
|
{
|
|
mNeedUndistort = !mNeedUndistort;
|
|
}
|
|
|
|
void ShowProcessor::setUndistort(bool isEnabled)
|
|
{
|
|
mNeedUndistort = isEnabled;
|
|
}
|
|
|
|
ShowProcessor::~ShowProcessor()
|
|
{
|
|
|
|
}
|