int floodFill( std::vector<CvFFillSegment>& buffer, cv::InputOutputArray _imageId, cv::InputOutputArray _image, cv::Point seedPoint, int channel, double scaleFactor, int& compCounter, long threshold, int maxSize, int minCompSize, cv::Mat& segmImg, cv::Mat& segmMap, cv::Rect& rect, int& area, std::unordered_map<int, int>& keypointHash, std::vector<int>& keypointIds, bool resegment, bool gradFill, int srcCols, cv::Scalar loDiff, cv::Scalar upDiff) { CvConnectedComp ccomp; CvMat c_image = _image.getMat(); CvMat c_imageId = _imageId.getMat(); if(! resegment ) { int* checkRow = (int*) (c_imageId.data.ptr + seedPoint.y * c_imageId.step); if(checkRow[seedPoint.x] > 0) return checkRow[seedPoint.x]; } compCounter++; floodFillC(buffer, &c_imageId, &c_image, seedPoint, channel, compCounter, loDiff, upDiff, &ccomp, threshold, maxSize, segmMap, gradFill); rect = ccomp.rect; if( ccomp.area == -1 ) return -2; if( ccomp.area < minCompSize ) return -1; segmImg = cv::Mat::zeros( ccomp.rect.height, ccomp.rect.width, CV_8UC1 ); for (int y = 0; y < ccomp.rect.height; y++ ) { int* rowId = (int*)(c_imageId.data.ptr + c_imageId.step * (y + ccomp.rect.y)); uchar* rowSegm = &segmImg.at<uchar>(y * segmImg.step); int ybase = ((int) roundf(((y + ccomp.rect.y)))) * srcCols; for(int x = 0; x < ccomp.rect.width; x++) { if( rowId[x + ccomp.rect.x] == compCounter) { rowSegm[x] = 255; int index = ( (ybase) + roundf((x + ccomp.rect.x))); if( keypointHash.find( index ) != keypointHash.end() ) { keypointIds.push_back(keypointHash[index]); } #ifndef NDEBUG segmMap.at<uchar>(y + ccomp.rect.y, x + ccomp.rect.x) = 255; #endif } } } area = ccomp.area; return compCounter; }
void sortKeyPoints(std::vector<cv::KeyPoint>& keypoints, cv::InputOutputArray _descriptors) { std::vector<size_t> indexies(keypoints.size()); for (size_t i = 0; i < indexies.size(); ++i) indexies[i] = i; std::sort(indexies.begin(), indexies.end(), KeypointIdxCompare(&keypoints)); std::vector<cv::KeyPoint> new_keypoints; cv::Mat new_descriptors; new_keypoints.resize(keypoints.size()); cv::Mat descriptors; if (_descriptors.needed()) { descriptors = _descriptors.getMat(); new_descriptors.create(descriptors.size(), descriptors.type()); } for (size_t i = 0; i < indexies.size(); ++i) { size_t new_idx = indexies[i]; new_keypoints[i] = keypoints[new_idx]; if (!new_descriptors.empty()) descriptors.row((int) new_idx).copyTo(new_descriptors.row((int) i)); } keypoints.swap(new_keypoints); if (_descriptors.needed()) new_descriptors.copyTo(_descriptors); }
void fftShift(cv::InputOutputArray _out) { cv::Mat out = _out.getMat(); if(out.rows == 1 && out.cols == 1) { // trivially shifted. return; } std::vector<cv::Mat> planes; planes.push_back(out); int xMid = out.cols >> 1; int yMid = out.rows >> 1; bool is_1d = xMid == 0 || yMid == 0; if(is_1d) { xMid = xMid + yMid; for(size_t i = 0; i < planes.size(); i++) { Mat tmp; Mat half0(planes[i], Rect(0, 0, xMid, 1)); Mat half1(planes[i], Rect(xMid, 0, xMid, 1)); half0.copyTo(tmp); half1.copyTo(half0); tmp.copyTo(half1); } } else { for(size_t i = 0; i < planes.size(); i++) { // perform quadrant swaps... Mat tmp; Mat q0(planes[i], Rect(0, 0, xMid, yMid)); Mat q1(planes[i], Rect(xMid, 0, xMid, yMid)); Mat q2(planes[i], Rect(0, yMid, xMid, yMid)); Mat q3(planes[i], Rect(xMid, yMid, xMid, yMid)); q0.copyTo(tmp); q3.copyTo(q0); tmp.copyTo(q3); q1.copyTo(tmp); q2.copyTo(q1); tmp.copyTo(q2); } } merge(planes, out); }