deepin-ocr/3rdparty/opencv-4.5.4/modules/imgproc/test/test_intelligent_scissors.cpp

// This file is part of OpenCV project.
// It is subject to the license terms in the LICENSE file found in the top-level directory
// of this distribution and at http://opencv.org/license.html.

#include "test_precomp.hpp"
//#include "opencv2/imgproc/segmentation.hpp"

namespace opencv_test { namespace {


Mat getTestImageGray()
{
    static Mat m;
    if (m.empty())
    {
        m = imread(findDataFile("shared/lena.png"), IMREAD_GRAYSCALE);
    }
    return m.clone();
}

Mat getTestImageColor()
{
    static Mat m;
    if (m.empty())
    {
        m = imread(findDataFile("shared/lena.png"), IMREAD_COLOR);
    }
    return m.clone();
}

Mat getTestImage1()
{
    static Mat m;
    if (m.empty())
    {
        m.create(Size(200, 100), CV_8UC1);
        m.setTo(Scalar::all(128));
        Rect roi(50, 30, 100, 40);
        m(roi).setTo(Scalar::all(0));
#if 0
        imshow("image", m);
        waitKey();
#endif
    }
    return m.clone();
}

Mat getTestImage2()
{
    static Mat m;
    if (m.empty())
    {
        m.create(Size(200, 100), CV_8UC1);
        m.setTo(Scalar::all(128));
        Rect roi(40, 30, 100, 40);
        m(roi).setTo(Scalar::all(255));
#if 0
        imshow("image", m);
        waitKey();
#endif
    }
    return m.clone();
}

Mat getTestImage3()
{
    static Mat m;
    if (m.empty())
    {
        m.create(Size(200, 100), CV_8UC1);
        m.setTo(Scalar::all(128));
        Scalar color(0,0,0,0);
        line(m, Point(30, 50), Point(50, 50), color, 1);
        line(m, Point(50, 50), Point(80, 30), color, 1);
        line(m, Point(150, 50), Point(80, 30), color, 1);
        line(m, Point(150, 50), Point(180, 50), color, 1);

        line(m, Point(80, 10), Point(80, 90), Scalar::all(200), 1);
        line(m, Point(100, 10), Point(100, 90), Scalar::all(200), 1);
        line(m, Point(120, 10), Point(120, 90), Scalar::all(200), 1);
#if 0
        imshow("image", m);
        waitKey();
#endif
    }
    return m.clone();
}

Mat getTestImage4()
{
    static Mat m;
    if (m.empty())
    {
        m.create(Size(200, 100), CV_8UC1);
        for (int y = 0; y < m.rows; y++)
        {
            for (int x = 0; x < m.cols; x++)
            {
                float dx = (float)(x - 100);
                float dy = (float)(y - 100);
                float d = sqrtf(dx * dx + dy * dy);
                m.at<uchar>(y, x) = saturate_cast<uchar>(100 + 100 * sin(d / 10 * CV_PI));
            }
        }
#if 0
        imshow("image", m);
        waitKey();
#endif
    }
    return m.clone();
}

Mat getTestImage5()
{
    static Mat m;
    if (m.empty())
    {
        m.create(Size(200, 100), CV_8UC1);
        for (int y = 0; y < m.rows; y++)
        {
            for (int x = 0; x < m.cols; x++)
            {
                float dx = (float)(x - 100);
                float dy = (float)(y - 100);
                float d = sqrtf(dx * dx + dy * dy);
                m.at<uchar>(y, x) = saturate_cast<uchar>(x / 2 + 100 * sin(d / 10 * CV_PI));
            }
        }
#if 0
        imshow("image", m);
        waitKey();
#endif
    }
    return m.clone();
}

void show(const Mat& img, const std::vector<Point> pts)
{
    if (cvtest::debugLevel >= 10)
    {
        Mat dst = img.clone();
        std::vector< std::vector<Point> > contours;
        contours.push_back(pts);
        polylines(dst, contours, false, Scalar::all(255));
        imshow("dst", dst);
        waitKey();
    }
}

TEST(Imgproc_IntelligentScissorsMB, rect)
{
    segmentation::IntelligentScissorsMB tool;

    tool.applyImage(getTestImage1());

    Point source_point(50, 30);
    tool.buildMap(source_point);

    Point target_point(100, 30);
    std::vector<Point> pts;
    tool.getContour(target_point, pts);

    tool.applyImage(getTestImage2());

    tool.buildMap(source_point);

    std::vector<Point> pts2;
    tool.getContour(target_point, pts2, true/*backward*/);

    EXPECT_EQ(pts.size(), pts2.size());
}

TEST(Imgproc_IntelligentScissorsMB, lines)
{
    segmentation::IntelligentScissorsMB tool;
    Mat image = getTestImage3();
    tool.applyImage(image);

    Point source_point(30, 50);
    tool.buildMap(source_point);

    Point target_point(150, 50);
    std::vector<Point> pts;
    tool.getContour(target_point, pts);

    EXPECT_EQ((size_t)121, pts.size());
    show(image, pts);
}

TEST(Imgproc_IntelligentScissorsMB, circles)
{
    segmentation::IntelligentScissorsMB tool;
    tool.setGradientMagnitudeMaxLimit(10);

    Mat image = getTestImage4();
    tool.applyImage(image);

    Point source_point(50, 50);
    tool.buildMap(source_point);

    Point target_point(150, 50);
    std::vector<Point> pts;
    tool.getContour(target_point, pts);

    EXPECT_EQ((size_t)101, pts.size());
    show(image, pts);
}

TEST(Imgproc_IntelligentScissorsMB, circles_gradient)
{
    segmentation::IntelligentScissorsMB tool;
    Mat image = getTestImage5();
    tool.applyImage(image);

    Point source_point(50, 50);
    tool.buildMap(source_point);

    Point target_point(150, 50);
    std::vector<Point> pts;
    tool.getContour(target_point, pts);

    EXPECT_EQ((size_t)101, pts.size());
    show(image, pts);
}

#define PTS_SIZE_EPS 2

TEST(Imgproc_IntelligentScissorsMB, grayscale)
{
    segmentation::IntelligentScissorsMB tool;

    Mat image = getTestImageGray();
    tool.applyImage(image);

    Point source_point(275, 63);
    tool.buildMap(source_point);

    Point target_point(413, 155);
    std::vector<Point> pts;
    tool.getContour(target_point, pts);

    size_t gold = 206;
    EXPECT_GE(pts.size(), gold - PTS_SIZE_EPS);
    EXPECT_LE(pts.size(), gold + PTS_SIZE_EPS);
    show(image, pts);
}

TEST(Imgproc_IntelligentScissorsMB, check_features_grayscale_1_0_0_zerro_crossing_with_limit)
{
    segmentation::IntelligentScissorsMB tool;
    tool.setEdgeFeatureZeroCrossingParameters(64);
    tool.setWeights(1.0f, 0.0f, 0.0f);

    Mat image = getTestImageGray();
    tool.applyImage(image);

    Point source_point(275, 63);
    tool.buildMap(source_point);

    Point target_point(413, 155);
    std::vector<Point> pts;
    tool.getContour(target_point, pts);

    size_t gold = 207;
    EXPECT_GE(pts.size(), gold - PTS_SIZE_EPS);
    EXPECT_LE(pts.size(), gold + PTS_SIZE_EPS);
    show(image, pts);
}

TEST(Imgproc_IntelligentScissorsMB, check_features_grayscale_1_0_0_canny)
{
    segmentation::IntelligentScissorsMB tool;
    tool.setEdgeFeatureCannyParameters(50, 100);
    tool.setWeights(1.0f, 0.0f, 0.0f);

    Mat image = getTestImageGray();
    tool.applyImage(image);

    Point source_point(275, 63);
    tool.buildMap(source_point);

    Point target_point(413, 155);
    std::vector<Point> pts;
    tool.getContour(target_point, pts);

    size_t gold = 201;
    EXPECT_GE(pts.size(), gold - PTS_SIZE_EPS);
    EXPECT_LE(pts.size(), gold + PTS_SIZE_EPS);
    show(image, pts);
}

TEST(Imgproc_IntelligentScissorsMB, check_features_grayscale_0_1_0)
{
    segmentation::IntelligentScissorsMB tool;
    tool.setWeights(0.0f, 1.0f, 0.0f);

    Mat image = getTestImageGray();
    tool.applyImage(image);

    Point source_point(275, 63);
    tool.buildMap(source_point);

    Point target_point(413, 155);
    std::vector<Point> pts;
    tool.getContour(target_point, pts);

    size_t gold = 166;
    EXPECT_GE(pts.size(), gold - PTS_SIZE_EPS);
    EXPECT_LE(pts.size(), gold + PTS_SIZE_EPS);
    show(image, pts);
}

TEST(Imgproc_IntelligentScissorsMB, check_features_grayscale_0_0_1)
{
    segmentation::IntelligentScissorsMB tool;
    tool.setWeights(0.0f, 0.0f, 1.0f);

    Mat image = getTestImageGray();
    tool.applyImage(image);

    Point source_point(275, 63);
    tool.buildMap(source_point);

    Point target_point(413, 155);
    std::vector<Point> pts;
    tool.getContour(target_point, pts);

    size_t gold = 197;
    EXPECT_GE(pts.size(), gold - PTS_SIZE_EPS);
    EXPECT_LE(pts.size(), gold + PTS_SIZE_EPS);
    show(image, pts);
}

TEST(Imgproc_IntelligentScissorsMB, color)
{
    segmentation::IntelligentScissorsMB tool;

    Mat image = getTestImageColor();
    tool.applyImage(image);

    Point source_point(275, 63);
    tool.buildMap(source_point);

    Point target_point(413, 155);
    std::vector<Point> pts;
    tool.getContour(target_point, pts);

    size_t gold = 205;
    EXPECT_GE(pts.size(), gold - PTS_SIZE_EPS);
    EXPECT_LE(pts.size(), gold + PTS_SIZE_EPS);
    show(image, pts);
}

TEST(Imgproc_IntelligentScissorsMB, color_canny)
{
    segmentation::IntelligentScissorsMB tool;
    tool.setEdgeFeatureCannyParameters(32, 100);

    Mat image = getTestImageColor();
    tool.applyImage(image);

    Point source_point(275, 63);
    tool.buildMap(source_point);

    Point target_point(413, 155);
    std::vector<Point> pts;
    tool.getContour(target_point, pts);

    size_t gold = 200;
    EXPECT_GE(pts.size(), gold - PTS_SIZE_EPS);
    EXPECT_LE(pts.size(), gold + PTS_SIZE_EPS);
    show(image, pts);
}


TEST(Imgproc_IntelligentScissorsMB, color_custom_features_invalid)
{
    segmentation::IntelligentScissorsMB tool;
    ASSERT_ANY_THROW(tool.applyImageFeatures(noArray(), noArray(), noArray()));
}

TEST(Imgproc_IntelligentScissorsMB, color_custom_features_edge)
{
    segmentation::IntelligentScissorsMB tool;

    Mat image = getTestImageColor();

    Mat canny_edges;
    Canny(image, canny_edges, 32, 100, 5);
    Mat binary_edge_feature;
    cv::threshold(canny_edges, binary_edge_feature, 254, 1, THRESH_BINARY_INV);
    tool.applyImageFeatures(binary_edge_feature, noArray(), noArray(), image);

    Point source_point(275, 63);
    tool.buildMap(source_point);

    Point target_point(413, 155);
    std::vector<Point> pts;
    tool.getContour(target_point, pts);

    size_t gold = 201;
    EXPECT_GE(pts.size(), gold - PTS_SIZE_EPS);
    EXPECT_LE(pts.size(), gold + PTS_SIZE_EPS);
    show(image, pts);
}

TEST(Imgproc_IntelligentScissorsMB, color_custom_features_all)
{
    segmentation::IntelligentScissorsMB tool;

    tool.setWeights(0.9f, 0.0f, 0.1f);

    Mat image = getTestImageColor();

    Mat canny_edges;
    Canny(image, canny_edges, 50, 100, 5);
    Mat binary_edge_feature; // 0, 1 values
    cv::threshold(canny_edges, binary_edge_feature, 254, 1, THRESH_BINARY_INV);

    Mat_<Point2f> gradient_direction(image.size(), Point2f(0, 0));  // normalized
    Mat_<float> gradient_magnitude(image.size(), 0);  // cost function
    tool.applyImageFeatures(binary_edge_feature, gradient_direction, gradient_magnitude);

    Point source_point(275, 63);
    tool.buildMap(source_point);

    Point target_point(413, 155);
    std::vector<Point> pts;
    tool.getContour(target_point, pts);

    size_t gold = 201;
    EXPECT_GE(pts.size(), gold - PTS_SIZE_EPS);
    EXPECT_LE(pts.size(), gold + PTS_SIZE_EPS);
    show(image, pts);
}

TEST(Imgproc_IntelligentScissorsMB, color_custom_features_edge_magnitude)
{
    segmentation::IntelligentScissorsMB tool;

    tool.setWeights(0.9f, 0.0f, 0.1f);

    Mat image = getTestImageColor();

    Mat canny_edges;
    Canny(image, canny_edges, 50, 100, 5);
    Mat binary_edge_feature; // 0, 1 values
    cv::threshold(canny_edges, binary_edge_feature, 254, 1, THRESH_BINARY_INV);

    Mat_<float> gradient_magnitude(image.size(), 0);  // cost function
    tool.applyImageFeatures(binary_edge_feature, noArray(), gradient_magnitude);

    Point source_point(275, 63);
    tool.buildMap(source_point);

    Point target_point(413, 155);
    std::vector<Point> pts;
    tool.getContour(target_point, pts);

    size_t gold = 201;
    EXPECT_GE(pts.size(), gold - PTS_SIZE_EPS);
    EXPECT_LE(pts.size(), gold + PTS_SIZE_EPS);
    show(image, pts);
}


}} // namespace
feat: 切换后端至PaddleOCR-NCNN，切换工程为CMake 1.项目后端整体迁移至PaddleOCR-NCNN算法，已通过基本的兼容性测试 2.工程改为使用CMake组织，后续为了更好地兼容第三方库，不再提供QMake工程 3.重整权利声明文件，重整代码工程，确保最小化侵权风险 Log: 切换后端至PaddleOCR-NCNN，切换工程为CMake Change-Id: I4d5d2c5d37505a4a24b389b1a4c5d12f17bfa38c 2022-05-10 09:54:44 +08:00			`// This file is part of OpenCV project.`
			`// It is subject to the license terms in the LICENSE file found in the top-level directory`
			`// of this distribution and at http://opencv.org/license.html.`

			`#include "test_precomp.hpp"`
			`//#include "opencv2/imgproc/segmentation.hpp"`

			`namespace opencv_test { namespace {`


			`Mat getTestImageGray()`
			`{`
			`static Mat m;`
			`if (m.empty())`
			`{`
			`m = imread(findDataFile("shared/lena.png"), IMREAD_GRAYSCALE);`
			`}`
			`return m.clone();`
			`}`

			`Mat getTestImageColor()`
			`{`
			`static Mat m;`
			`if (m.empty())`
			`{`
			`m = imread(findDataFile("shared/lena.png"), IMREAD_COLOR);`
			`}`
			`return m.clone();`
			`}`

			`Mat getTestImage1()`
			`{`
			`static Mat m;`
			`if (m.empty())`
			`{`
			`m.create(Size(200, 100), CV_8UC1);`
			`m.setTo(Scalar::all(128));`
			`Rect roi(50, 30, 100, 40);`
			`m(roi).setTo(Scalar::all(0));`
			`#if 0`
			`imshow("image", m);`
			`waitKey();`
			`#endif`
			`}`
			`return m.clone();`
			`}`

			`Mat getTestImage2()`
			`{`
			`static Mat m;`
			`if (m.empty())`
			`{`
			`m.create(Size(200, 100), CV_8UC1);`
			`m.setTo(Scalar::all(128));`
			`Rect roi(40, 30, 100, 40);`
			`m(roi).setTo(Scalar::all(255));`
			`#if 0`
			`imshow("image", m);`
			`waitKey();`
			`#endif`
			`}`
			`return m.clone();`
			`}`

			`Mat getTestImage3()`
			`{`
			`static Mat m;`
			`if (m.empty())`
			`{`
			`m.create(Size(200, 100), CV_8UC1);`
			`m.setTo(Scalar::all(128));`
			`Scalar color(0,0,0,0);`
			`line(m, Point(30, 50), Point(50, 50), color, 1);`
			`line(m, Point(50, 50), Point(80, 30), color, 1);`
			`line(m, Point(150, 50), Point(80, 30), color, 1);`
			`line(m, Point(150, 50), Point(180, 50), color, 1);`

			`line(m, Point(80, 10), Point(80, 90), Scalar::all(200), 1);`
			`line(m, Point(100, 10), Point(100, 90), Scalar::all(200), 1);`
			`line(m, Point(120, 10), Point(120, 90), Scalar::all(200), 1);`
			`#if 0`
			`imshow("image", m);`
			`waitKey();`
			`#endif`
			`}`
			`return m.clone();`
			`}`

			`Mat getTestImage4()`
			`{`
			`static Mat m;`
			`if (m.empty())`
			`{`
			`m.create(Size(200, 100), CV_8UC1);`
			`for (int y = 0; y < m.rows; y++)`
			`{`
			`for (int x = 0; x < m.cols; x++)`
			`{`
			`float dx = (float)(x - 100);`
			`float dy = (float)(y - 100);`
			`float d = sqrtf(dx * dx + dy * dy);`
			`m.at<uchar>(y, x) = saturate_cast<uchar>(100 + 100 * sin(d / 10 * CV_PI));`
			`}`
			`}`
			`#if 0`
			`imshow("image", m);`
			`waitKey();`
			`#endif`
			`}`
			`return m.clone();`
			`}`

			`Mat getTestImage5()`
			`{`
			`static Mat m;`
			`if (m.empty())`
			`{`
			`m.create(Size(200, 100), CV_8UC1);`
			`for (int y = 0; y < m.rows; y++)`
			`{`
			`for (int x = 0; x < m.cols; x++)`
			`{`
			`float dx = (float)(x - 100);`
			`float dy = (float)(y - 100);`
			`float d = sqrtf(dx * dx + dy * dy);`
			`m.at<uchar>(y, x) = saturate_cast<uchar>(x / 2 + 100 * sin(d / 10 * CV_PI));`
			`}`
			`}`
			`#if 0`
			`imshow("image", m);`
			`waitKey();`
			`#endif`
			`}`
			`return m.clone();`
			`}`

			`void show(const Mat& img, const std::vector<Point> pts)`
			`{`
			`if (cvtest::debugLevel >= 10)`
			`{`
			`Mat dst = img.clone();`
			`std::vector< std::vector<Point> > contours;`
			`contours.push_back(pts);`
			`polylines(dst, contours, false, Scalar::all(255));`
			`imshow("dst", dst);`
			`waitKey();`
			`}`
			`}`

			`TEST(Imgproc_IntelligentScissorsMB, rect)`
			`{`
			`segmentation::IntelligentScissorsMB tool;`

			`tool.applyImage(getTestImage1());`

			`Point source_point(50, 30);`
			`tool.buildMap(source_point);`

			`Point target_point(100, 30);`
			`std::vector<Point> pts;`
			`tool.getContour(target_point, pts);`

			`tool.applyImage(getTestImage2());`

			`tool.buildMap(source_point);`

			`std::vector<Point> pts2;`
			`tool.getContour(target_point, pts2, true/backward/);`

			`EXPECT_EQ(pts.size(), pts2.size());`
			`}`

			`TEST(Imgproc_IntelligentScissorsMB, lines)`
			`{`
			`segmentation::IntelligentScissorsMB tool;`
			`Mat image = getTestImage3();`
			`tool.applyImage(image);`

			`Point source_point(30, 50);`
			`tool.buildMap(source_point);`

			`Point target_point(150, 50);`
			`std::vector<Point> pts;`
			`tool.getContour(target_point, pts);`

			`EXPECT_EQ((size_t)121, pts.size());`
			`show(image, pts);`
			`}`

			`TEST(Imgproc_IntelligentScissorsMB, circles)`
			`{`
			`segmentation::IntelligentScissorsMB tool;`
			`tool.setGradientMagnitudeMaxLimit(10);`

			`Mat image = getTestImage4();`
			`tool.applyImage(image);`

			`Point source_point(50, 50);`
			`tool.buildMap(source_point);`

			`Point target_point(150, 50);`
			`std::vector<Point> pts;`
			`tool.getContour(target_point, pts);`

			`EXPECT_EQ((size_t)101, pts.size());`
			`show(image, pts);`
			`}`

			`TEST(Imgproc_IntelligentScissorsMB, circles_gradient)`
			`{`
			`segmentation::IntelligentScissorsMB tool;`
			`Mat image = getTestImage5();`
			`tool.applyImage(image);`

			`Point source_point(50, 50);`
			`tool.buildMap(source_point);`

			`Point target_point(150, 50);`
			`std::vector<Point> pts;`
			`tool.getContour(target_point, pts);`

			`EXPECT_EQ((size_t)101, pts.size());`
			`show(image, pts);`
			`}`

			`#define PTS_SIZE_EPS 2`

			`TEST(Imgproc_IntelligentScissorsMB, grayscale)`
			`{`
			`segmentation::IntelligentScissorsMB tool;`

			`Mat image = getTestImageGray();`
			`tool.applyImage(image);`

			`Point source_point(275, 63);`
			`tool.buildMap(source_point);`

			`Point target_point(413, 155);`
			`std::vector<Point> pts;`
			`tool.getContour(target_point, pts);`

			`size_t gold = 206;`
			`EXPECT_GE(pts.size(), gold - PTS_SIZE_EPS);`
			`EXPECT_LE(pts.size(), gold + PTS_SIZE_EPS);`
			`show(image, pts);`
			`}`

			`TEST(Imgproc_IntelligentScissorsMB, check_features_grayscale_1_0_0_zerro_crossing_with_limit)`
			`{`
			`segmentation::IntelligentScissorsMB tool;`
			`tool.setEdgeFeatureZeroCrossingParameters(64);`
			`tool.setWeights(1.0f, 0.0f, 0.0f);`

			`Mat image = getTestImageGray();`
			`tool.applyImage(image);`

			`Point source_point(275, 63);`
			`tool.buildMap(source_point);`

			`Point target_point(413, 155);`
			`std::vector<Point> pts;`
			`tool.getContour(target_point, pts);`

			`size_t gold = 207;`
			`EXPECT_GE(pts.size(), gold - PTS_SIZE_EPS);`
			`EXPECT_LE(pts.size(), gold + PTS_SIZE_EPS);`
			`show(image, pts);`
			`}`

			`TEST(Imgproc_IntelligentScissorsMB, check_features_grayscale_1_0_0_canny)`
			`{`
			`segmentation::IntelligentScissorsMB tool;`
			`tool.setEdgeFeatureCannyParameters(50, 100);`
			`tool.setWeights(1.0f, 0.0f, 0.0f);`

			`Mat image = getTestImageGray();`
			`tool.applyImage(image);`

			`Point source_point(275, 63);`
			`tool.buildMap(source_point);`

			`Point target_point(413, 155);`
			`std::vector<Point> pts;`
			`tool.getContour(target_point, pts);`

			`size_t gold = 201;`
			`EXPECT_GE(pts.size(), gold - PTS_SIZE_EPS);`
			`EXPECT_LE(pts.size(), gold + PTS_SIZE_EPS);`
			`show(image, pts);`
			`}`

			`TEST(Imgproc_IntelligentScissorsMB, check_features_grayscale_0_1_0)`
			`{`
			`segmentation::IntelligentScissorsMB tool;`
			`tool.setWeights(0.0f, 1.0f, 0.0f);`

			`Mat image = getTestImageGray();`
			`tool.applyImage(image);`

			`Point source_point(275, 63);`
			`tool.buildMap(source_point);`

			`Point target_point(413, 155);`
			`std::vector<Point> pts;`
			`tool.getContour(target_point, pts);`

			`size_t gold = 166;`
			`EXPECT_GE(pts.size(), gold - PTS_SIZE_EPS);`
			`EXPECT_LE(pts.size(), gold + PTS_SIZE_EPS);`
			`show(image, pts);`
			`}`

			`TEST(Imgproc_IntelligentScissorsMB, check_features_grayscale_0_0_1)`
			`{`
			`segmentation::IntelligentScissorsMB tool;`
			`tool.setWeights(0.0f, 0.0f, 1.0f);`

			`Mat image = getTestImageGray();`
			`tool.applyImage(image);`

			`Point source_point(275, 63);`
			`tool.buildMap(source_point);`

			`Point target_point(413, 155);`
			`std::vector<Point> pts;`
			`tool.getContour(target_point, pts);`

			`size_t gold = 197;`
			`EXPECT_GE(pts.size(), gold - PTS_SIZE_EPS);`
			`EXPECT_LE(pts.size(), gold + PTS_SIZE_EPS);`
			`show(image, pts);`
			`}`

			`TEST(Imgproc_IntelligentScissorsMB, color)`
			`{`
			`segmentation::IntelligentScissorsMB tool;`

			`Mat image = getTestImageColor();`
			`tool.applyImage(image);`

			`Point source_point(275, 63);`
			`tool.buildMap(source_point);`

			`Point target_point(413, 155);`
			`std::vector<Point> pts;`
			`tool.getContour(target_point, pts);`

			`size_t gold = 205;`
			`EXPECT_GE(pts.size(), gold - PTS_SIZE_EPS);`
			`EXPECT_LE(pts.size(), gold + PTS_SIZE_EPS);`
			`show(image, pts);`
			`}`

			`TEST(Imgproc_IntelligentScissorsMB, color_canny)`
			`{`
			`segmentation::IntelligentScissorsMB tool;`
			`tool.setEdgeFeatureCannyParameters(32, 100);`

			`Mat image = getTestImageColor();`
			`tool.applyImage(image);`

			`Point source_point(275, 63);`
			`tool.buildMap(source_point);`

			`Point target_point(413, 155);`
			`std::vector<Point> pts;`
			`tool.getContour(target_point, pts);`

			`size_t gold = 200;`
			`EXPECT_GE(pts.size(), gold - PTS_SIZE_EPS);`
			`EXPECT_LE(pts.size(), gold + PTS_SIZE_EPS);`
			`show(image, pts);`
			`}`


			`TEST(Imgproc_IntelligentScissorsMB, color_custom_features_invalid)`
			`{`
			`segmentation::IntelligentScissorsMB tool;`
			`ASSERT_ANY_THROW(tool.applyImageFeatures(noArray(), noArray(), noArray()));`
			`}`

			`TEST(Imgproc_IntelligentScissorsMB, color_custom_features_edge)`
			`{`
			`segmentation::IntelligentScissorsMB tool;`

			`Mat image = getTestImageColor();`

			`Mat canny_edges;`
			`Canny(image, canny_edges, 32, 100, 5);`
			`Mat binary_edge_feature;`
			`cv::threshold(canny_edges, binary_edge_feature, 254, 1, THRESH_BINARY_INV);`
			`tool.applyImageFeatures(binary_edge_feature, noArray(), noArray(), image);`

			`Point source_point(275, 63);`
			`tool.buildMap(source_point);`

			`Point target_point(413, 155);`
			`std::vector<Point> pts;`
			`tool.getContour(target_point, pts);`

			`size_t gold = 201;`
			`EXPECT_GE(pts.size(), gold - PTS_SIZE_EPS);`
			`EXPECT_LE(pts.size(), gold + PTS_SIZE_EPS);`
			`show(image, pts);`
			`}`

			`TEST(Imgproc_IntelligentScissorsMB, color_custom_features_all)`
			`{`
			`segmentation::IntelligentScissorsMB tool;`

			`tool.setWeights(0.9f, 0.0f, 0.1f);`

			`Mat image = getTestImageColor();`

			`Mat canny_edges;`
			`Canny(image, canny_edges, 50, 100, 5);`
			`Mat binary_edge_feature; // 0, 1 values`
			`cv::threshold(canny_edges, binary_edge_feature, 254, 1, THRESH_BINARY_INV);`

			`Mat_<Point2f> gradient_direction(image.size(), Point2f(0, 0)); // normalized`
			`Mat_<float> gradient_magnitude(image.size(), 0); // cost function`
			`tool.applyImageFeatures(binary_edge_feature, gradient_direction, gradient_magnitude);`

			`Point source_point(275, 63);`
			`tool.buildMap(source_point);`

			`Point target_point(413, 155);`
			`std::vector<Point> pts;`
			`tool.getContour(target_point, pts);`

			`size_t gold = 201;`
			`EXPECT_GE(pts.size(), gold - PTS_SIZE_EPS);`
			`EXPECT_LE(pts.size(), gold + PTS_SIZE_EPS);`
			`show(image, pts);`
			`}`

			`TEST(Imgproc_IntelligentScissorsMB, color_custom_features_edge_magnitude)`
			`{`
			`segmentation::IntelligentScissorsMB tool;`

			`tool.setWeights(0.9f, 0.0f, 0.1f);`

			`Mat image = getTestImageColor();`

			`Mat canny_edges;`
			`Canny(image, canny_edges, 50, 100, 5);`
			`Mat binary_edge_feature; // 0, 1 values`
			`cv::threshold(canny_edges, binary_edge_feature, 254, 1, THRESH_BINARY_INV);`

			`Mat_<float> gradient_magnitude(image.size(), 0); // cost function`
			`tool.applyImageFeatures(binary_edge_feature, noArray(), gradient_magnitude);`

			`Point source_point(275, 63);`
			`tool.buildMap(source_point);`

			`Point target_point(413, 155);`
			`std::vector<Point> pts;`
			`tool.getContour(target_point, pts);`

			`size_t gold = 201;`
			`EXPECT_GE(pts.size(), gold - PTS_SIZE_EPS);`
			`EXPECT_LE(pts.size(), gold + PTS_SIZE_EPS);`
			`show(image, pts);`
			`}`


			`}} // namespace`