#include "opencv2/core.hpp" #include "opencv2/video/tracking.hpp" #include "opencv2/imgproc.hpp" #include "opencv2/highgui.hpp" #include "opencv2/ml.hpp" using namespace cv; using namespace cv::ml; struct Data { Mat img; Mat samples; //Set of train samples. Contains points on image Mat responses; //Set of responses for train samples Data() { const int WIDTH = 841; const int HEIGHT = 594; img = Mat::zeros(HEIGHT, WIDTH, CV_8UC3); imshow("Train svmsgd", img); } }; //Train with SVMSGD algorithm //(samples, responses) is a train set //weights is a required vector for decision function of SVMSGD algorithm bool doTrain(const Mat samples, const Mat responses, Mat &weights, float &shift); //function finds two points for drawing line (wx = 0) bool findPointsForLine(const Mat &weights, float shift, Point points[], int width, int height); // function finds cross point of line (wx = 0) and segment ( (y = HEIGHT, 0 <= x <= WIDTH) or (x = WIDTH, 0 <= y <= HEIGHT) ) bool findCrossPointWithBorders(const Mat &weights, float shift, const std::pair &segment, Point &crossPoint); //segments' initialization ( (y = HEIGHT, 0 <= x <= WIDTH) and (x = WIDTH, 0 <= y <= HEIGHT) ) void fillSegments(std::vector > &segments, int width, int height); //redraw points' set and line (wx = 0) void redraw(Data data, const Point points[2]); //add point in train set, train SVMSGD algorithm and draw results on image void addPointRetrainAndRedraw(Data &data, int x, int y, int response); bool doTrain( const Mat samples, const Mat responses, Mat &weights, float &shift) { cv::Ptr svmsgd = SVMSGD::create(); cv::Ptr trainData = TrainData::create(samples, cv::ml::ROW_SAMPLE, responses); svmsgd->train( trainData ); if (svmsgd->isTrained()) { weights = svmsgd->getWeights(); shift = svmsgd->getShift(); return true; } return false; } void fillSegments(std::vector > &segments, int width, int height) { std::pair currentSegment; currentSegment.first = Point(width, 0); currentSegment.second = Point(width, height); segments.push_back(currentSegment); currentSegment.first = Point(0, height); currentSegment.second = Point(width, height); segments.push_back(currentSegment); currentSegment.first = Point(0, 0); currentSegment.second = Point(width, 0); segments.push_back(currentSegment); currentSegment.first = Point(0, 0); currentSegment.second = Point(0, height); segments.push_back(currentSegment); } bool findCrossPointWithBorders(const Mat &weights, float shift, const std::pair &segment, Point &crossPoint) { int x = 0; int y = 0; int xMin = std::min(segment.first.x, segment.second.x); int xMax = std::max(segment.first.x, segment.second.x); int yMin = std::min(segment.first.y, segment.second.y); int yMax = std::max(segment.first.y, segment.second.y); CV_Assert(weights.type() == CV_32FC1); CV_Assert(xMin == xMax || yMin == yMax); if (xMin == xMax && weights.at(1) != 0) { x = xMin; y = static_cast(std::floor( - (weights.at(0) * x + shift) / weights.at(1))); if (y >= yMin && y <= yMax) { crossPoint.x = x; crossPoint.y = y; return true; } } else if (yMin == yMax && weights.at(0) != 0) { y = yMin; x = static_cast(std::floor( - (weights.at(1) * y + shift) / weights.at(0))); if (x >= xMin && x <= xMax) { crossPoint.x = x; crossPoint.y = y; return true; } } return false; } bool findPointsForLine(const Mat &weights, float shift, Point points[2], int width, int height) { if (weights.empty()) { return false; } int foundPointsCount = 0; std::vector > segments; fillSegments(segments, width, height); for (uint i = 0; i < segments.size(); i++) { if (findCrossPointWithBorders(weights, shift, segments[i], points[foundPointsCount])) foundPointsCount++; if (foundPointsCount >= 2) break; } return true; } void redraw(Data data, const Point points[2]) { data.img.setTo(0); Point center; int radius = 3; Scalar color; CV_Assert((data.samples.type() == CV_32FC1) && (data.responses.type() == CV_32FC1)); for (int i = 0; i < data.samples.rows; i++) { center.x = static_cast(data.samples.at(i,0)); center.y = static_cast(data.samples.at(i,1)); color = (data.responses.at(i) > 0) ? Scalar(128,128,0) : Scalar(0,128,128); circle(data.img, center, radius, color, 5); } line(data.img, points[0], points[1],cv::Scalar(1,255,1)); imshow("Train svmsgd", data.img); } void addPointRetrainAndRedraw(Data &data, int x, int y, int response) { Mat currentSample(1, 2, CV_32FC1); currentSample.at(0,0) = (float)x; currentSample.at(0,1) = (float)y; data.samples.push_back(currentSample); data.responses.push_back(static_cast(response)); Mat weights(1, 2, CV_32FC1); float shift = 0; if (doTrain(data.samples, data.responses, weights, shift)) { Point points[2]; findPointsForLine(weights, shift, points, data.img.cols, data.img.rows); redraw(data, points); } } static void onMouse( int event, int x, int y, int, void* pData) { Data &data = *(Data*)pData; switch( event ) { case EVENT_LBUTTONUP: addPointRetrainAndRedraw(data, x, y, 1); break; case EVENT_RBUTTONDOWN: addPointRetrainAndRedraw(data, x, y, -1); break; } } int main() { Data data; setMouseCallback( "Train svmsgd", onMouse, &data ); waitKey(); return 0; }