root/modules/cudaimgproc/src/canny.cpp

DEFINITIONS

1. createCannyEdgeDetector
2. L2gradient_
3. setLowThreshold
4. getLowThreshold
5. setHighThreshold
6. getHighThreshold
7. setAppertureSize
8. getAppertureSize
9. setL2Gradient
10. getL2Gradient
11. write
12. read
13. detect
14. detect
15. createBuf
16. CannyCaller
17. createCannyEdgeDetector

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#include "precomp.hpp"

using namespace cv;
using namespace cv::cuda;

#if !defined (HAVE_CUDA) || defined (CUDA_DISABLER)

Ptr<CannyEdgeDetector> cv::cuda::createCannyEdgeDetector(double, double, int, bool) { throw_no_cuda(); return Ptr<CannyEdgeDetector>(); }

#else /* !defined (HAVE_CUDA) */

namespace canny
{
    void calcMagnitude(PtrStepSzb srcWhole, int xoff, int yoff, PtrStepSzi dx, PtrStepSzi dy, PtrStepSzf mag, bool L2Grad, cudaStream_t stream);
    void calcMagnitude(PtrStepSzi dx, PtrStepSzi dy, PtrStepSzf mag, bool L2Grad, cudaStream_t stream);

    void calcMap(PtrStepSzi dx, PtrStepSzi dy, PtrStepSzf mag, PtrStepSzi map, float low_thresh, float high_thresh, cudaStream_t stream);

    void edgesHysteresisLocal(PtrStepSzi map, short2* st1, cudaStream_t stream);

    void edgesHysteresisGlobal(PtrStepSzi map, short2* st1, short2* st2, cudaStream_t stream);

    void getEdges(PtrStepSzi map, PtrStepSzb dst, cudaStream_t stream);
}

namespace
{
    class CannyImpl : public CannyEdgeDetector
    {
    public:
        CannyImpl(double low_thresh, double high_thresh, int apperture_size, bool L2gradient) :
            low_thresh_(low_thresh), high_thresh_(high_thresh), apperture_size_(apperture_size), L2gradient_(L2gradient)
        {
            old_apperture_size_ = -1;
        }

        void detect(InputArray image, OutputArray edges, Stream& stream);
        void detect(InputArray dx, InputArray dy, OutputArray edges, Stream& stream);

        void setLowThreshold(double low_thresh) { low_thresh_ = low_thresh; }
        double getLowThreshold() const { return low_thresh_; }

        void setHighThreshold(double high_thresh) { high_thresh_ = high_thresh; }
        double getHighThreshold() const { return high_thresh_; }

        void setAppertureSize(int apperture_size) { apperture_size_ = apperture_size; }
        int getAppertureSize() const { return apperture_size_; }

        void setL2Gradient(bool L2gradient) { L2gradient_ = L2gradient; }
        bool getL2Gradient() const { return L2gradient_; }

        void write(FileStorage& fs) const
        {
            fs << "name" << "Canny_CUDA"
            << "low_thresh" << low_thresh_
            << "high_thresh" << high_thresh_
            << "apperture_size" << apperture_size_
            << "L2gradient" << L2gradient_;
        }

        void read(const FileNode& fn)
        {
            CV_Assert( String(fn["name"]) == "Canny_CUDA" );
            low_thresh_ = (double)fn["low_thresh"];
            high_thresh_ = (double)fn["high_thresh"];
            apperture_size_ = (int)fn["apperture_size"];
            L2gradient_ = (int)fn["L2gradient"] != 0;
        }

    private:
        void createBuf(Size image_size);
        void CannyCaller(GpuMat& edges, Stream& stream);

        double low_thresh_;
        double high_thresh_;
        int apperture_size_;
        bool L2gradient_;

        GpuMat dx_, dy_;
        GpuMat mag_;
        GpuMat map_;
        GpuMat st1_, st2_;
#ifdef HAVE_OPENCV_CUDAFILTERS
        Ptr<Filter> filterDX_, filterDY_;
#endif
        int old_apperture_size_;
    };

    void CannyImpl::detect(InputArray _image, OutputArray _edges, Stream& stream)
    {
        GpuMat image = _image.getGpuMat();

        CV_Assert( image.type() == CV_8UC1 );
        CV_Assert( deviceSupports(SHARED_ATOMICS) );

        if (low_thresh_ > high_thresh_)
            std::swap(low_thresh_, high_thresh_);

        createBuf(image.size());

        _edges.create(image.size(), CV_8UC1);
        GpuMat edges = _edges.getGpuMat();

        if (apperture_size_ == 3)
        {
            Size wholeSize;
            Point ofs;
            image.locateROI(wholeSize, ofs);
            GpuMat srcWhole(wholeSize, image.type(), image.datastart, image.step);

            canny::calcMagnitude(srcWhole, ofs.x, ofs.y, dx_, dy_, mag_, L2gradient_, StreamAccessor::getStream(stream));
        }
        else
        {
#ifndef HAVE_OPENCV_CUDAFILTERS
            throw_no_cuda();
#else
            filterDX_->apply(image, dx_, stream);
            filterDY_->apply(image, dy_, stream);

            canny::calcMagnitude(dx_, dy_, mag_, L2gradient_, StreamAccessor::getStream(stream));
#endif
        }

        CannyCaller(edges, stream);
    }

    void CannyImpl::detect(InputArray _dx, InputArray _dy, OutputArray _edges, Stream& stream)
    {
        GpuMat dx = _dx.getGpuMat();
        GpuMat dy = _dy.getGpuMat();

        CV_Assert( dx.type() == CV_32SC1 );
        CV_Assert( dy.type() == dx.type() && dy.size() == dx.size() );
        CV_Assert( deviceSupports(SHARED_ATOMICS) );

        dx.copyTo(dx_, stream);
        dy.copyTo(dy_, stream);

        if (low_thresh_ > high_thresh_)
            std::swap(low_thresh_, high_thresh_);

        createBuf(dx.size());

        _edges.create(dx.size(), CV_8UC1);
        GpuMat edges = _edges.getGpuMat();

        canny::calcMagnitude(dx_, dy_, mag_, L2gradient_, StreamAccessor::getStream(stream));

        CannyCaller(edges, stream);
    }

    void CannyImpl::createBuf(Size image_size)
    {
        CV_Assert(image_size.width < std::numeric_limits<short>::max() && image_size.height < std::numeric_limits<short>::max());

        ensureSizeIsEnough(image_size, CV_32SC1, dx_);
        ensureSizeIsEnough(image_size, CV_32SC1, dy_);

#ifdef HAVE_OPENCV_CUDAFILTERS
        if (apperture_size_ != 3 && apperture_size_ != old_apperture_size_)
        {
            filterDX_ = cuda::createDerivFilter(CV_8UC1, CV_32S, 1, 0, apperture_size_, false, 1, BORDER_REPLICATE);
            filterDY_ = cuda::createDerivFilter(CV_8UC1, CV_32S, 0, 1, apperture_size_, false, 1, BORDER_REPLICATE);
            old_apperture_size_ = apperture_size_;
        }
#endif

        ensureSizeIsEnough(image_size, CV_32FC1, mag_);
        ensureSizeIsEnough(image_size, CV_32SC1, map_);

        ensureSizeIsEnough(1, image_size.area(), CV_16SC2, st1_);
        ensureSizeIsEnough(1, image_size.area(), CV_16SC2, st2_);
    }

    void CannyImpl::CannyCaller(GpuMat& edges, Stream& stream)
    {
        map_.setTo(Scalar::all(0));
        canny::calcMap(dx_, dy_, mag_, map_, static_cast<float>(low_thresh_), static_cast<float>(high_thresh_), StreamAccessor::getStream(stream));

        canny::edgesHysteresisLocal(map_, st1_.ptr<short2>(), StreamAccessor::getStream(stream));

        canny::edgesHysteresisGlobal(map_, st1_.ptr<short2>(), st2_.ptr<short2>(), StreamAccessor::getStream(stream));

        canny::getEdges(map_, edges, StreamAccessor::getStream(stream));
    }
}

Ptr<CannyEdgeDetector> cv::cuda::createCannyEdgeDetector(double low_thresh, double high_thresh, int apperture_size, bool L2gradient)
{
    return makePtr<CannyImpl>(low_thresh, high_thresh, apperture_size, L2gradient);
}

#endif /* !defined (HAVE_CUDA) */