359 lines
12 KiB
C++
359 lines
12 KiB
C++
#include "ImageApplyOutHole.h"
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#include "ImageProcess_Public.h"
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#ifdef LOG
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#include "Device/filetools.h"
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#endif // LOG
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CImageApplyOutHole::CImageApplyOutHole(void)
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: CImageApply()
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, m_borderSize(20)
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, m_edgeScale(0.1f, 0.1f , 0.1f, 0.1f)
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, m_threshold(50)
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{
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}
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CImageApplyOutHole::CImageApplyOutHole(float borderSize, cv::Vec4f edgeScale, double threshold)
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: CImageApply()
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, m_borderSize(borderSize)
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, m_edgeScale(edgeScale)
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, m_threshold(threshold)
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{
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}
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CImageApplyOutHole::~CImageApplyOutHole(void)
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{
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}
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void CImageApplyOutHole::apply(cv::Mat& pDib, int side)
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{
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(void)pDib;
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(void)side;
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}
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void CImageApplyOutHole::apply(std::vector<cv::Mat>& mats, bool isTwoSide)
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{
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#ifdef LOG
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FileTools::write_log("imgprc.txt", "enter ImageOutHole apply");
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#endif // LOG
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if (mats.size() < 2)
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{
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#ifdef LOG
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FileTools::write_log("imgprc.txt", "exit ImageOutHole apply");
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#endif // LOG
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return;
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}
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if (mats[0].empty() || mats[1].empty())
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{
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#ifdef LOG
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FileTools::write_log("imgprc.txt", "exit ImageOutHole apply");
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#endif // LOG
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return;
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}
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//二值化正反面图像
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cv::Mat front = mats[0];
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cv::Mat back = mats[1];
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cv::Mat front_thre, back_thre;
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hg::threshold_Mat(front, front_thre, m_threshold);
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hg::threshold_Mat(back, back_thre, m_threshold);
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cv::Mat element = getStructuringElement(cv::MORPH_RECT, cv::Size(10, 1));
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cv::morphologyEx(front_thre, front_thre, cv::MORPH_OPEN, element, cv::Point(-1, -1), 1, cv::BORDER_CONSTANT, cv::Scalar::all(0));
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cv::morphologyEx(back_thre, back_thre, cv::MORPH_OPEN, element, cv::Point(-1, -1), 1, cv::BORDER_CONSTANT, cv::Scalar::all(0));
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//反面二值化图像水平翻转
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cv::flip(back_thre, back_thre, 1); //1:Horizontal
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//正反面图像寻边
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std::vector<std::vector<cv::Point>> contours_front, contours_back;
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std::vector<cv::Vec4i> b1_front, b1_back;
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hg::findContours(front_thre.clone(), contours_front, b1_front, cv::RETR_EXTERNAL);
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hg::findContours(back_thre.clone(), contours_back, b1_back, cv::RETR_EXTERNAL);
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//提取正反面图像最大轮廓
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std::vector<cv::Point> maxContour_front = hg::getMaxContour(contours_front, b1_front);
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std::vector<cv::Point> maxContour_back = hg::getMaxContour(contours_back, b1_back);
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if (maxContour_front.empty() || maxContour_back.empty())
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return;
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cv::RotatedRect rrect_front = hg::getBoundingRect(maxContour_front); //提取正面最大轮廓的最小外接矩形
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cv::RotatedRect rrect_back = hg::getBoundingRect(maxContour_back); //提取反面最大轮廓的最小外接矩形
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//如果正反面图像尺寸差异超过20个像素,直接放弃处理
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if (cv::abs(rrect_front.size.width - rrect_back.size.width) > 20 ||
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cv::abs(rrect_front.size.height - rrect_back.size.height) > 20)
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return;
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//提取正反面图像重叠部分区域
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cv::Rect roi_front, roi_back;
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cv::RotatedRect mask_rotatedRect;
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getRoi(rrect_front, rrect_back, front.size(), back.size(), roi_front, roi_back, mask_rotatedRect);
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cv::Mat roiMat_front(front_thre, roi_front); //在正面二值图像中截取重叠部分
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cv::Mat roiMat_back(back_thre, roi_back); //在反面二值图像中截取重叠部分
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//cv::imwrite("roiMat_front.jpg", roiMat_front);
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//cv::imwrite("roiMat_back.jpg", roiMat_back);
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//正反面二值图像做或运算,真正镂空区域保留0,其他地方填充为255
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cv::Mat mask;
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cv::bitwise_or(roiMat_front, roiMat_back, mask); //或运算,正反面二值图像重叠
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//cv::imwrite("mask1.jpg", mask);
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//二值图像重叠图像颜色取反,膨胀,提取轮廓
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cv::bitwise_not(mask, mask);
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//cv::imwrite("mask2.jpg", mask); //反色
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element = cv::getStructuringElement(cv::MORPH_ELLIPSE, cv::Size(10, 10));
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cv::dilate(mask, mask, element, cv::Point(-1, -1), 1, cv::BORDER_CONSTANT, cv::Scalar(255)); //膨胀算法,增大孔洞连通区域面积
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//cv::imwrite("mask3.jpg", mask);
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//为了避免孔洞彻底贯穿纸边,人为绘制纸张轮廓,确保所有孔洞为封闭图形,不会与背景粘连
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cv::polylines(mask, hg::getVertices(mask_rotatedRect), true, cv::Scalar(255), 15); //绘制纸张矩形边缘
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//cv::imwrite("mask4.jpg", mask);
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std::vector<std::vector<cv::Point>> contours_mask;
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std::vector<cv::Vec4i> b1_mask;
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hg::findContours(mask, contours_mask, b1_mask, cv::RETR_TREE); //提取重叠图像轮廓
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//过滤非孔洞的联通区域
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std::vector<std::vector<cv::Point>> hole_contours = filterPoly(contours_mask, b1_mask, mask_rotatedRect, m_edgeScale, m_borderSize);
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cv::Scalar color = getBackGroudColor(front(roi_front), rrect_front.size.area());
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for (size_t i = 0; i < hole_contours.size(); i++)
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{
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std::vector<std::vector<cv::Point>> contourss_temp;
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contourss_temp.push_back(hole_contours[i]);
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cv::Mat front_temp = front(roi_front);
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hg::fillPolys(front_temp, contourss_temp, color);
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}
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if (isTwoSide)
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{
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int width_ = roi_back.width;
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roi_back.x = back.cols - roi_back.width - roi_back.x; //因为之前反面图像翻转,所以现在ROI也要进行相应翻转
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color = getBackGroudColor(back(roi_back), rrect_front.size.area());
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hole_contours.clear();
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hole_contours = filterPoly(contours_mask, b1_mask, mask_rotatedRect, cv::Vec4f(m_edgeScale[0], m_edgeScale[1], m_edgeScale[2], m_edgeScale[3]), m_borderSize);
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for (size_t i = 0; i < hole_contours.size(); i++)
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{
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std::vector<cv::Point> hole_contour;
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for (size_t j = 0; j < hole_contours[i].size(); j++)
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hole_contour.push_back(cv::Point(width_ - hole_contours[i][j].x - 1, hole_contours[i][j].y));
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std::vector<std::vector<cv::Point>> contours_temp;
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contours_temp.push_back(hole_contour);
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cv::Mat back_temp = back(roi_back);
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hg::fillPolys(back_temp, contours_temp, color);
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}
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}
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#ifdef LOG
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FileTools::write_log("imgprc.txt", "exit ImageOutHole apply");
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#endif // LOG
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}
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void CImageApplyOutHole::getRoi(cv::RotatedRect rrect_front, cv::RotatedRect rrect_back, const cv::Size& srcSize_front, const cv::Size& srcSize_back, cv::Rect& roi_front,
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cv::Rect& roi_back, cv::RotatedRect& mask_rotatedRect)
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{
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cv::Rect roi_front_ = rrect_front.boundingRect();
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cv::Rect roi_back_ = rrect_back.boundingRect();
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cv::Size meanSize = (roi_front_.size() + roi_back_.size()) / 2;
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roi_front_.x += (roi_front_.width - meanSize.width) / 2;
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roi_front_.width = meanSize.width;
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roi_front_.y += (roi_front_.height - meanSize.height) / 2;
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roi_front_.height = meanSize.height;
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roi_back_.x += (roi_back_.width - meanSize.width) / 2;
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roi_back_.width = meanSize.width;
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roi_back_.y += (roi_back_.height - meanSize.height) / 2;
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roi_back_.height = meanSize.height;
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mask_rotatedRect.angle = (rrect_front.angle + rrect_back.angle) / 2;
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mask_rotatedRect.size = (rrect_front.size + rrect_back.size) / 2.0f;
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mask_rotatedRect.center = cv::Point2f(roi_front_.size().width + roi_back_.size().width, roi_front_.size().height + roi_back_.size().height) / 4.0f;
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roi_front = roi_front_ & cv::Rect(cv::Point(0, 0), srcSize_front);
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roi_back = roi_back_ & cv::Rect(cv::Point(0, 0), srcSize_back);
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int offset_left_f = roi_front.x - roi_front_.x;
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int offset_left_b = roi_back.x - roi_back_.x;
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int offset_top_f = roi_front.y - roi_front_.y;
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int offset_top_b = roi_back.y - roi_back_.y;
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int offset_right_f = roi_front_.br().x - roi_front.br().x;
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int offset_right_b = roi_back_.br().x - roi_back.br().x;
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int offset_bottom_f = roi_front_.br().y - roi_front.br().y;
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int offset_bottom_b = roi_back_.br().y - roi_back.br().y;
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if (offset_left_f > offset_left_b)
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{
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roi_back.x += offset_left_f - offset_left_b;
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roi_back.width -= offset_left_f - offset_left_b;
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mask_rotatedRect.center.x -= offset_left_f - offset_left_b;
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}
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else
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{
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roi_front.x += offset_left_b - offset_left_f;
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roi_front.width -= offset_left_b - offset_left_f;
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mask_rotatedRect.center.x -= offset_left_b - offset_left_f;
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}
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if (offset_top_f > offset_top_b)
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{
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roi_back.y += offset_top_f - offset_top_b;
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roi_back.height -= offset_top_f - offset_top_b;
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mask_rotatedRect.center.y -= offset_top_f - offset_top_b;
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}
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else
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{
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roi_front.y += offset_top_b - offset_top_f;
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roi_front.height -= offset_top_b - offset_top_f;
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mask_rotatedRect.center.y -= offset_top_b - offset_top_f;
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}
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if (offset_right_f > offset_right_b)
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roi_back.width -= offset_right_f - offset_right_b;
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else
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roi_front.width -= offset_right_b - offset_right_f;
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if (offset_bottom_f > offset_bottom_b)
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roi_back.height -= offset_bottom_f - offset_bottom_b;
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else
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roi_front.height -= offset_bottom_b - offset_bottom_f;
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}
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#define SIDE_LENGTH_UP_SCALE 6
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#define PI 3.14159265359f
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std::vector<std::vector<cv::Point>> CImageApplyOutHole::filterPoly(std::vector<std::vector<cv::Point>>& contours, std::vector<cv::Vec4i>& m,
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cv::RotatedRect roi, cv::Vec4f edgeScale, float sideLengthLow)
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{
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cv::RotatedRect roi2(roi.center,
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cv::Size2f(roi.size.width * (1 - edgeScale[0] - edgeScale[1]), roi.size.height * (1 - edgeScale[2] - edgeScale[3])),
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roi.angle);
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cv::Point2f offset_0(roi.size.width * (edgeScale[0] - edgeScale[1]) / 2 + roi.center.x, roi.size.height * (edgeScale[2] - edgeScale[3]) / 2 + roi.center.y);
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roi2.center.x = (offset_0.x - roi.center.x) * cos(roi.angle * PI / 180.0f) - (offset_0.y - roi.center.y) * sin(roi2.angle * PI / 180.0f) + roi.center.x;
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roi2.center.y = (offset_0.x - roi.center.x) * sin(roi.angle * PI / 180.0f) + (offset_0.y - roi.center.y) * cos(roi2.angle * PI / 180.0f) + roi.center.y;
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std::vector<cv::Point> vertices_roi1 = hg::getVertices(roi);
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std::vector<cv::Point> vertices_roi2 = hg::getVertices(roi2);
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std::vector<std::vector<cv::Point>> hole_contours;
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for (size_t i = 0; i < contours.size(); i++)
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{
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if (m[i][2] != -1)
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{
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contours.erase(contours.begin() + i);
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m.erase(m.begin() + i);
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continue;
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}
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cv::RotatedRect rrect = hg::getBoundingRect(contours[i]);
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if (rrect.size.width < sideLengthLow ||
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rrect.size.height < sideLengthLow ||
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rrect.size.width > sideLengthLow * SIDE_LENGTH_UP_SCALE ||
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rrect.size.height > sideLengthLow * SIDE_LENGTH_UP_SCALE)
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{
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contours.erase(contours.begin() + i);
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m.erase(m.begin() + i);
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continue;
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}
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bool enabled = true;
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for (size_t j = 0, count = contours[i].size(); j < count; j++)
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{
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cv::Point p(contours[i][j]);
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double temp1 = pointPolygonTest(vertices_roi1, p, false); //判断是否在纸张内 1:内;0:上;-1:外
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double temp2 = pointPolygonTest(vertices_roi2, p, false); //判断是否在边缘区域内 1:内;0:上;-1:外
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//如果在纸张外,或者边缘内,视为非孔洞
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if (temp1 < 0 || temp2 > 0)
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{
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enabled = false;
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break;
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}
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}
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if (enabled)
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hole_contours.push_back(contours[i]);
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}
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return hole_contours;
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}
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cv::Scalar CImageApplyOutHole::getBackGroudColor(const cv::Mat& image, const std::vector<cv::Point> pixelPoints)
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{
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if (pixelPoints.empty()) return cv::Scalar(255, 255, 255);
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int channels = image.channels();
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int temp[3] = { 0 };
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for (size_t i = 0, length = pixelPoints.size(); i < length; ++i)
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{
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int x = cv::min(cv::max(0, pixelPoints[i].x), image.cols - 1);
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int y = cv::min(cv::max(0, pixelPoints[i].y), image.rows - 1);
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const unsigned char* ptr = image.ptr(y, x);
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for (int j = 0; j < channels; ++j)
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temp[j] += ptr[j];
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}
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return cv::Scalar(temp[0] / static_cast<int>(pixelPoints.size()),
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temp[1] / static_cast<int>(pixelPoints.size()),
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temp[2] / static_cast<int>(pixelPoints.size()));
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}
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cv::Scalar CImageApplyOutHole::getBackGroudColor(const cv::Mat& image, int total)
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{
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if (image.channels() == 3)
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{
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cv::Mat image_bgr[3];
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cv::split(image, image_bgr);
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uchar bgr[3];
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for (size_t i = 0; i < 3; i++)
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bgr[i] = getBackGroudChannelMean(image_bgr[i], total);
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return cv::Scalar(bgr[0], bgr[1], bgr[2]);
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}
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else
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return cv::Scalar::all(getBackGroudChannelMean(image, total));
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}
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uchar CImageApplyOutHole::getBackGroudChannelMean(const cv::Mat& gray, int total)
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{
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cv::Mat image_clone;
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cv::resize(gray, image_clone, cv::Size(), 0.25, 0.25);
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int threnshold = total / 32;
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int channels[] = { 0 };
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int nHistSize[] = { 256 };
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float range[] = { 0, 256 };
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const float* fHistRanges[] = { range };
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cv::Mat hist;
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cv::calcHist(&image_clone, 1, channels, cv::Mat(), hist, 1, nHistSize, fHistRanges, true, false);
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int hist_array[256];
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for (int i = 0; i < 256; i++)
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hist_array[i] = hist.at<float>(i, 0);
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int length = 1;
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const int length_max = 255;
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while (length < length_max)
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{
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for (size_t i = 1; i < 256 - length; i++)
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{
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int count = 0;
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uint pixSum = 0;
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for (size_t j = 0; j < length; j++)
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{
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count += hist_array[j + i];
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pixSum += hist_array[j + i] * (i + j);
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}
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if (count >= threnshold)
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return pixSum / count;
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}
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length++;
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}
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return 255;
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} |