d1/d9e/fld_lines_8cpp-example.html

#include <iostream>


#include "opencv2/imgproc.hpp"

#include "opencv2/ximgproc.hpp"

#include "opencv2/imgcodecs.hpp"

#include "opencv2/highgui.hpp"


using namespace std;

using namespace cv;

using namespace cv::ximgproc;


int main(int argc, char** argv)

{

    string in;

    CommandLineParser parser(argc, argv, "{@input|corridor.jpg|input image}{help h||show help message}");

    if (parser.has("help"))

    {

        parser.printMessage();

        return 0;

    }

    in = samples::findFile(parser.get<string>("@input"));


    Mat image = imread(in, IMREAD_GRAYSCALE);


    if( image.empty() )

    {

        return -1;

    }


    // Create FLD detector

    // Param               Default value   Description

    // length_threshold    10            - Segments shorter than this will be discarded

    // distance_threshold  1.41421356    - A point placed from a hypothesis line

    //                                     segment farther than this will be

    //                                     regarded as an outlier

    // canny_th1           50            - First threshold for

    //                                     hysteresis procedure in Canny()

    // canny_th2           50            - Second threshold for

    //                                     hysteresis procedure in Canny()

    // canny_aperture_size 3            - Aperturesize for the sobel operator in Canny().

    //                                     If zero, Canny() is not applied and the input

    //                                     image is taken as an edge image.

    // do_merge            false         - If true, incremental merging of segments

    //                                     will be performed

    int length_threshold = 10;

    float distance_threshold = 1.41421356f;

    double canny_th1 = 50.0;

    double canny_th2 = 50.0;

    int canny_aperture_size = 3;

    bool do_merge = false;

    Ptr<FastLineDetector> fld = createFastLineDetector(length_threshold,

            distance_threshold, canny_th1, canny_th2, canny_aperture_size,

            do_merge);

    vector<Vec4f> lines;


    // Because of some CPU's power strategy, it seems that the first running of

    // an algorithm takes much longer. So here we run the algorithm 10 times

    // to see the algorithm's processing time with sufficiently warmed-up

    // CPU performance.

    for (int run_count = 0; run_count < 5; run_count++) {

        double freq = getTickFrequency();

        lines.clear();

        int64 start = getTickCount();

        // Detect the lines with FLD

        fld->detect(image, lines);

        double duration_ms = double(getTickCount() - start) * 1000 / freq;

        cout << "Elapsed time for FLD " << duration_ms << " ms." << endl;

    }


    // Show found lines with FLD

    Mat line_image_fld(image);

    fld->drawSegments(line_image_fld, lines);

    imshow("FLD result", line_image_fld);


    waitKey(1);


    Ptr<EdgeDrawing> ed = createEdgeDrawing();

    ed->params.EdgeDetectionOperator = EdgeDrawing::SOBEL;

    ed->params.GradientThresholdValue = 38;

    ed->params.AnchorThresholdValue = 8;


    vector<Vec6d> ellipses;


    for (int run_count = 0; run_count < 5; run_count++) {

        double freq = getTickFrequency();

        lines.clear();

        int64 start = getTickCount();


        // Detect edges

        //you should call this before detectLines() and detectEllipses()

        ed->detectEdges(image);


        // Detect lines

        ed->detectLines(lines);

        double duration_ms = double(getTickCount() - start) * 1000 / freq;

        cout << "Elapsed time for EdgeDrawing detectLines " << duration_ms << " ms." << endl;


        start = getTickCount();

        // Detect circles and ellipses

        ed->detectEllipses(ellipses);

        duration_ms = double(getTickCount() - start) * 1000 / freq;

        cout << "Elapsed time for EdgeDrawing detectEllipses " << duration_ms << " ms." << endl;

    }


    Mat edge_image_ed = Mat::zeros(image.size(), CV_8UC3);

    vector<vector<Point> > segments = ed->getSegments();


    for (size_t i = 0; i < segments.size(); i++)

    {

        const Point* pts = &segments[i][0];

        int n = (int)segments[i].size();

        polylines(edge_image_ed, &pts, &n, 1, false, Scalar((rand() & 255), (rand() & 255), (rand() & 255)), 1);

    }


    imshow("EdgeDrawing detected edges", edge_image_ed);


    Mat line_image_ed(image);

    fld->drawSegments(line_image_ed, lines);


    // Draw circles and ellipses

    for (size_t i = 0; i < ellipses.size(); i++)

    {

        Point center((int)ellipses[i][0], (int)ellipses[i][1]);

        Size axes((int)ellipses[i][2] + (int)ellipses[i][3], (int)ellipses[i][2] + (int)ellipses[i][4]);

        double angle(ellipses[i][5]);

        Scalar color = ellipses[i][2] == 0 ? Scalar(255, 255, 0) : Scalar(0, 255, 0);


        ellipse(line_image_ed, center, axes, angle, 0, 360, color, 2, LINE_AA);

    }


    imshow("EdgeDrawing result", line_image_ed);

    waitKey();

    return 0;

}

cv::Point
Point2i Point
Definition: modules/core/include/opencv2/core/types.hpp:209

cv::Size
Size2i Size
Definition: modules/core/include/opencv2/core/types.hpp:370

cv::Scalar
Scalar_< double > Scalar
Definition: modules/core/include/opencv2/core/types.hpp:709

int64
int64_t int64
Definition: core/include/opencv2/core/hal/interface.h:61

CV_8UC3
#define CV_8UC3
Definition: core/include/opencv2/core/hal/interface.h:90

cv::samples::findFile
cv::String findFile(const cv::String &relative_path, bool required=true, bool silentMode=false)
Try to find requested data file.

cv::getTickFrequency
double getTickFrequency()
Returns the number of ticks per second.

cv::getTickCount
int64 getTickCount()
Returns the number of ticks.

cv::imshow
void imshow(const String &winname, InputArray mat)
Displays an image in the specified window.

cv::waitKey
int waitKey(int delay=0)
Waits for a pressed key.

cv::IMREAD_GRAYSCALE
@ IMREAD_GRAYSCALE
If set, always convert image to the single channel grayscale image (codec internal conversion).
Definition: imgcodecs.hpp:70

cv::imread
CV_EXPORTS_W Mat imread(const String &filename, int flags=IMREAD_COLOR_BGR)
Loads an image from a file.

cv::ellipse
void ellipse(InputOutputArray img, Point center, Size axes, double angle, double startAngle, double endAngle, const Scalar &color, int thickness=1, int lineType=LINE_8, int shift=0)
Draws a simple or thick elliptic arc or fills an ellipse sector.

cv::polylines
void polylines(InputOutputArray img, InputArrayOfArrays pts, bool isClosed, const Scalar &color, int thickness=1, int lineType=LINE_8, int shift=0)
Draws several polygonal curves.

cv::LINE_AA
@ LINE_AA
antialiased line
Definition: imgproc/include/opencv2/imgproc.hpp:894

cv::ximgproc::createEdgeDrawing
Ptr< EdgeDrawing > createEdgeDrawing()
Creates a smart pointer to a EdgeDrawing object and initializes it.

cv::ximgproc::createFastLineDetector
Ptr< FastLineDetector > createFastLineDetector(int length_threshold=10, float distance_threshold=1.414213562f, double canny_th1=50.0, double canny_th2=50.0, int canny_aperture_size=3, bool do_merge=false)
Creates a smart pointer to a FastLineDetector object and initializes it.

highgui.hpp

main
int main(int argc, char *argv[])
Definition: highgui_qt.cpp:3

imgcodecs.hpp

imgproc.hpp

cv::gapi::streaming::size
GOpaque< Size > size(const GMat &src)
Gets dimensions from Mat.

cv::ximgproc
Definition: ximgproc.hpp:125

cv
Definition: core/include/opencv2/core.hpp:107

std
STL namespace.

ximgproc.hpp