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#include "precomp.hpp"

#include <algorithm>
#include <iterator>
#include <limits>

namespace cv
{

int RANSACUpdateNumIters( double p, double ep, int modelPoints, int maxIters )
{
    if( modelPoints <= 0 )
        CV_Error( Error::StsOutOfRange, "the number of model points should be positive" );

    p = MAX(p, 0.);
    p = MIN(p, 1.);
    ep = MAX(ep, 0.);
    ep = MIN(ep, 1.);

    // avoid inf's & nan's
    double num = MAX(1. - p, DBL_MIN);
    double denom = 1. - std::pow(1. - ep, modelPoints);
    if( denom < DBL_MIN )
        return 0;

    num = std::log(num);
    denom = std::log(denom);

    return denom >= 0 || -num >= maxIters*(-denom) ? maxIters : cvRound(num/denom);
}


class RANSACPointSetRegistrator : public PointSetRegistrator
{
public:
    RANSACPointSetRegistrator(const Ptr<PointSetRegistrator::Callback>& _cb=Ptr<PointSetRegistrator::Callback>(),
                              int _modelPoints=0, double _threshold=0, double _confidence=0.99, int _maxIters=1000)
      : cb(_cb), modelPoints(_modelPoints), threshold(_threshold), confidence(_confidence), maxIters(_maxIters) {}

    int findInliers( const Mat& m1, const Mat& m2, const Mat& model, Mat& err, Mat& mask, double thresh ) const
    {
        cb->computeError( m1, m2, model, err );
        mask.create(err.size(), CV_8U);

        CV_Assert( err.isContinuous() && err.type() == CV_32F && mask.isContinuous() && mask.type() == CV_8U);
        const float* errptr = err.ptr<float>();
        uchar* maskptr = mask.ptr<uchar>();
        float t = (float)(thresh*thresh);
        int i, n = (int)err.total(), nz = 0;
        for( i = 0; i < n; i++ )
        {
            int f = errptr[i] <= t;
            maskptr[i] = (uchar)f;
            nz += f;
        }
        return nz;
    }

    bool getSubset( const Mat& m1, const Mat& m2, Mat& ms1, Mat& ms2, RNG& rng, int maxAttempts=1000 ) const
    {
        cv::AutoBuffer<int> _idx(modelPoints);
        int* idx = _idx.data();

        const int d1 = m1.channels() > 1 ? m1.channels() : m1.cols;
        const int d2 = m2.channels() > 1 ? m2.channels() : m2.cols;

        int esz1 = (int)m1.elemSize1() * d1;
        int esz2 = (int)m2.elemSize1() * d2;
        CV_Assert((esz1 % sizeof(int)) == 0 && (esz2 % sizeof(int)) == 0);
        esz1 /= sizeof(int);
        esz2 /= sizeof(int);

        const int count = m1.checkVector(d1);
        const int count2 = m2.checkVector(d2);
        CV_Assert(count >= modelPoints && count == count2);

        const int *m1ptr = m1.ptr<int>();
        const int *m2ptr = m2.ptr<int>();

        ms1.create(modelPoints, 1, CV_MAKETYPE(m1.depth(), d1));
        ms2.create(modelPoints, 1, CV_MAKETYPE(m2.depth(), d2));

        int *ms1ptr = ms1.ptr<int>();
        int *ms2ptr = ms2.ptr<int>();

        for( int iters = 0; iters < maxAttempts; ++iters )
        {
            int i;

            for( i = 0; i < modelPoints; ++i )
            {
                int idx_i;

                for ( idx_i = rng.uniform(0, count);
                    std::find(idx, idx + i, idx_i) != idx + i;
                    idx_i = rng.uniform(0, count) )
                {}

                idx[i] = idx_i;

                for( int k = 0; k < esz1; ++k )
                    ms1ptr[i*esz1 + k] = m1ptr[idx_i*esz1 + k];

                for( int k = 0; k < esz2; ++k )
                    ms2ptr[i*esz2 + k] = m2ptr[idx_i*esz2 + k];
            }

            if( cb->checkSubset(ms1, ms2, i) )
                return true;
        }

        return false;
    }

    bool run(InputArray _m1, InputArray _m2, OutputArray _model, OutputArray _mask) const CV_OVERRIDE
    {
        bool result = false;
        Mat m1 = _m1.getMat(), m2 = _m2.getMat();
        Mat err, mask, model, bestModel, ms1, ms2;

        int iter, niters = MAX(maxIters, 1);
        int d1 = m1.channels() > 1 ? m1.channels() : m1.cols;
        int d2 = m2.channels() > 1 ? m2.channels() : m2.cols;
        int count = m1.checkVector(d1), count2 = m2.checkVector(d2), maxGoodCount = 0;

        RNG rng((uint64)-1);

        CV_Assert( cb );
        CV_Assert( confidence > 0 && confidence < 1 );

        CV_Assert( count >= 0 && count2 == count );
        if( count < modelPoints )
            return false;

        Mat bestMask0, bestMask;

        if( _mask.needed() )
        {
            _mask.create(count, 1, CV_8U, -1, true);
            bestMask0 = bestMask = _mask.getMat();
            CV_Assert( (bestMask.cols == 1 || bestMask.rows == 1) && (int)bestMask.total() == count );
        }
        else
        {
            bestMask.create(count, 1, CV_8U);
            bestMask0 = bestMask;
        }

        if( count == modelPoints )
        {
            if( cb->runKernel(m1, m2, bestModel) <= 0 )
                return false;
            bestModel.copyTo(_model);
            bestMask.setTo(Scalar::all(1));
            return true;
        }

        for( iter = 0; iter < niters; iter++ )
        {
            int i, nmodels;
            if( count > modelPoints )
            {
                bool found = getSubset( m1, m2, ms1, ms2, rng, 10000 );
                if( !found )
                {
                    if( iter == 0 )
                        return false;
                    break;
                }
            }

            nmodels = cb->runKernel( ms1, ms2, model );
            if( nmodels <= 0 )
                continue;
            CV_Assert( model.rows % nmodels == 0 );
            Size modelSize(model.cols, model.rows/nmodels);

            for( i = 0; i < nmodels; i++ )
            {
                Mat model_i = model.rowRange( i*modelSize.height, (i+1)*modelSize.height );
                int goodCount = findInliers( m1, m2, model_i, err, mask, threshold );

                if( goodCount > MAX(maxGoodCount, modelPoints-1) )
                {
                    std::swap(mask, bestMask);
                    model_i.copyTo(bestModel);
                    maxGoodCount = goodCount;
                    niters = RANSACUpdateNumIters( confidence, (double)(count - goodCount)/count, modelPoints, niters );
                }
            }
        }

        if( maxGoodCount > 0 )
        {
            if( bestMask.data != bestMask0.data )
            {
                if( bestMask.size() == bestMask0.size() )
                    bestMask.copyTo(bestMask0);
                else
                    transpose(bestMask, bestMask0);
            }
            bestModel.copyTo(_model);
            result = true;
        }
        else
            _model.release();

        return result;
    }

    void setCallback(const Ptr<PointSetRegistrator::Callback>& _cb) CV_OVERRIDE { cb = _cb; }

    Ptr<PointSetRegistrator::Callback> cb;
    int modelPoints;
    double threshold;
    double confidence;
    int maxIters;
};

class LMeDSPointSetRegistrator : public RANSACPointSetRegistrator
{
public:
    LMeDSPointSetRegistrator(const Ptr<PointSetRegistrator::Callback>& _cb=Ptr<PointSetRegistrator::Callback>(),
                              int _modelPoints=0, double _confidence=0.99, int _maxIters=1000)
    : RANSACPointSetRegistrator(_cb, _modelPoints, 0, _confidence, _maxIters) {}

    bool run(InputArray _m1, InputArray _m2, OutputArray _model, OutputArray _mask) const CV_OVERRIDE
    {
        const double outlierRatio = 0.45;
        bool result = false;
        Mat m1 = _m1.getMat(), m2 = _m2.getMat();
        Mat ms1, ms2, err, errf, model, bestModel, mask, mask0;

        int d1 = m1.channels() > 1 ? m1.channels() : m1.cols;
        int d2 = m2.channels() > 1 ? m2.channels() : m2.cols;
        int count = m1.checkVector(d1), count2 = m2.checkVector(d2);
        double minMedian = DBL_MAX;

        RNG rng((uint64)-1);

        CV_Assert( cb );
        CV_Assert( confidence > 0 && confidence < 1 );

        CV_Assert( count >= 0 && count2 == count );
        if( count < modelPoints )
            return false;

        if( _mask.needed() )
        {
            _mask.create(count, 1, CV_8U, -1, true);
            mask0 = mask = _mask.getMat();
            CV_Assert( (mask.cols == 1 || mask.rows == 1) && (int)mask.total() == count );
        }

        if( count == modelPoints )
        {
            if( cb->runKernel(m1, m2, bestModel) <= 0 )
                return false;
            bestModel.copyTo(_model);
            mask.setTo(Scalar::all(1));
            return true;
        }

        int iter, niters = RANSACUpdateNumIters(confidence, outlierRatio, modelPoints, maxIters);
        niters = MAX(niters, 3);

        for( iter = 0; iter < niters; iter++ )
        {
            int i, nmodels;
            if( count > modelPoints )
            {
                bool found = getSubset( m1, m2, ms1, ms2, rng );
                if( !found )
                {
                    if( iter == 0 )
                        return false;
                    break;
                }
            }

            nmodels = cb->runKernel( ms1, ms2, model );
            if( nmodels <= 0 )
                continue;

            CV_Assert( model.rows % nmodels == 0 );
            Size modelSize(model.cols, model.rows/nmodels);

            for( i = 0; i < nmodels; i++ )
            {
                Mat model_i = model.rowRange( i*modelSize.height, (i+1)*modelSize.height );
                cb->computeError( m1, m2, model_i, err );
                if( err.depth() != CV_32F )
                    err.convertTo(errf, CV_32F);
                else
                    errf = err;
                CV_Assert( errf.isContinuous() && errf.type() == CV_32F && (int)errf.total() == count );
                std::nth_element(errf.ptr<int>(), errf.ptr<int>() + count/2, errf.ptr<int>() + count);
                double median = errf.at<float>(count/2);

                if( median < minMedian )
                {
                    minMedian = median;
                    model_i.copyTo(bestModel);
                }
            }
        }

        if( minMedian < DBL_MAX )
        {
            double sigma = 2.5*1.4826*(1 + 5./(count - modelPoints))*std::sqrt(minMedian);
            sigma = MAX( sigma, 0.001 );

            count = findInliers( m1, m2, bestModel, err, mask, sigma );
            if( _mask.needed() && mask0.data != mask.data )
            {
                if( mask0.size() == mask.size() )
                    mask.copyTo(mask0);
                else
                    transpose(mask, mask0);
            }
            bestModel.copyTo(_model);
            result = count >= modelPoints;
        }
        else
            _model.release();

        return result;
    }

};

Ptr<PointSetRegistrator> createRANSACPointSetRegistrator(const Ptr<PointSetRegistrator::Callback>& _cb,
                                                         int _modelPoints, double _threshold,
                                                         double _confidence, int _maxIters)
{
    return Ptr<PointSetRegistrator>(
        new RANSACPointSetRegistrator(_cb, _modelPoints, _threshold, _confidence, _maxIters));
}


Ptr<PointSetRegistrator> createLMeDSPointSetRegistrator(const Ptr<PointSetRegistrator::Callback>& _cb,
                             int _modelPoints, double _confidence, int _maxIters)
{
    return Ptr<PointSetRegistrator>(
        new LMeDSPointSetRegistrator(_cb, _modelPoints, _confidence, _maxIters));
}


/*
 * Compute
 *  x    a b c   X     t1
 *  y  = d e f * Y  +  t2
 *  z    g h i   Z     t3
 *
 *  - every element in _m1 contains (X,Y,Z), which are called source points
 *  - every element in _m2 contains (x,y,z), which are called destination points
 *  - _model is of size 3x4, which contains
 *     a b c t1
 *     d e f t2
 *     g h i t3
 */
class Affine3DEstimatorCallback : public PointSetRegistrator::Callback
{
public:
    int runKernel( InputArray _m1, InputArray _m2, OutputArray _model ) const CV_OVERRIDE
    {
        Mat m1 = _m1.getMat(), m2 = _m2.getMat();
        const Point3f* from = m1.ptr<Point3f>();
        const Point3f* to   = m2.ptr<Point3f>();

        const int N = 12;
        double buf[N*N + N + N];
        Mat A(N, N, CV_64F, &buf[0]);
        Mat B(N, 1, CV_64F, &buf[0] + N*N);
        Mat X(N, 1, CV_64F, &buf[0] + N*N + N);
        double* Adata = A.ptr<double>();
        double* Bdata = B.ptr<double>();
        A = Scalar::all(0);

        for( int i = 0; i < (N/3); i++ )
        {
            Bdata[i*3] = to[i].x;
            Bdata[i*3+1] = to[i].y;
            Bdata[i*3+2] = to[i].z;

            double *aptr = Adata + i*3*N;
            for(int k = 0; k < 3; ++k)
            {
                aptr[0] = from[i].x;
                aptr[1] = from[i].y;
                aptr[2] = from[i].z;
                aptr[3] = 1.0;
                aptr += 16;
            }
        }

        solve(A, B, X, DECOMP_SVD);
        X.reshape(1, 3).copyTo(_model);

        return 1;
    }

    void computeError( InputArray _m1, InputArray _m2, InputArray _model, OutputArray _err ) const CV_OVERRIDE
    {
        Mat m1 = _m1.getMat(), m2 = _m2.getMat(), model = _model.getMat();
        const Point3f* from = m1.ptr<Point3f>();
        const Point3f* to   = m2.ptr<Point3f>();
        const double* F = model.ptr<double>();

        int count = m1.checkVector(3);
        CV_Assert( count > 0 );

        _err.create(count, 1, CV_32F);
        Mat err = _err.getMat();
        float* errptr = err.ptr<float>();

        for(int i = 0; i < count; i++ )
        {
            const Point3f& f = from[i];
            const Point3f& t = to[i];

            double a = F[0]*f.x + F[1]*f.y + F[ 2]*f.z + F[ 3] - t.x;
            double b = F[4]*f.x + F[5]*f.y + F[ 6]*f.z + F[ 7] - t.y;
            double c = F[8]*f.x + F[9]*f.y + F[10]*f.z + F[11] - t.z;

            errptr[i] = (float)(a*a + b*b + c*c);
        }
    }

    bool checkSubset( InputArray _ms1, InputArray _ms2, int count ) const CV_OVERRIDE
    {
        const float threshold = 0.996f;
        Mat ms1 = _ms1.getMat(), ms2 = _ms2.getMat();

        for( int inp = 1; inp <= 2; inp++ )
        {
            int j, k, i = count - 1;
            const Mat* msi = inp == 1 ? &ms1 : &ms2;
            const Point3f* ptr = msi->ptr<Point3f>();

            CV_Assert( count <= msi->rows );

            // check that the i-th selected point does not belong
            // to a line connecting some previously selected points
            for(j = 0; j < i; ++j)
            {
                Point3f d1 = ptr[j] - ptr[i];
                float n1 = d1.x*d1.x + d1.y*d1.y + d1.z*d1.z;

                for(k = 0; k < j; ++k)
                {
                    Point3f d2 = ptr[k] - ptr[i];
                    float denom = (d2.x*d2.x + d2.y*d2.y + d2.z*d2.z)*n1;
                    float num = d1.x*d2.x + d1.y*d2.y + d1.z*d2.z;

                    if( num*num > threshold*threshold*denom )
                        return false;
                }
            }
        }
        return true;
    }
};


/*
 * Compute
 *  x      X     t1
 *  y  =   Y  +  t2
 *  z      Z     t3
 *
 *  - every element in _m1 contains (X,Y,Z), which are called source points
 *  - every element in _m2 contains (x,y,z), which are called destination points
 *  - _model is of size 3x1, which contains
 *      t1
 *      t2
 *      t3
 */
class Translation3DEstimatorCallback CV_FINAL : public PointSetRegistrator::Callback
{
public:
    int runKernel( InputArray _m1, InputArray _m2, OutputArray _model ) const CV_OVERRIDE
    {

        Mat m1 = _m1.getMat(), m2 = _m2.getMat();
        const Point3f* from = m1.ptr<Point3f>();
        const Point3f* to   = m2.ptr<Point3f>();

        Matx13d T;

        // The optimal translation is the mean of the pointwise displacements
        for(int i = 0; i < 4; i++)
        {
            const Point3f& f = from[i];
            const Point3f& t = to[i];

            T(0, 0) = T(0, 0) + t.x - f.x;
            T(0, 1) = T(0, 1) + t.y - f.y;
            T(0, 2) = T(0, 2) + t.z - f.z;
        }
        T *= (1.0f / 4);
        Mat(T, false).copyTo(_model);
        return 1;
    }

    void computeError( InputArray _m1, InputArray _m2, InputArray _model, OutputArray _err ) const CV_OVERRIDE
    {
        Mat m1 = _m1.getMat(), m2 = _m2.getMat(), model = _model.getMat();
        const Point3f* from = m1.ptr<Point3f>();
        const Point3f* to   = m2.ptr<Point3f>();
        const double* F = model.ptr<double>();

        int count = m1.checkVector(3);
        CV_Assert( count > 0 );

        _err.create(count, 1, CV_32F);
        Mat err = _err.getMat();
        float* errptr = err.ptr<float>();

        for(int i = 0; i < count; i++ )
        {
            const Point3f& f = from[i];
            const Point3f& t = to[i];

            double a = F[0] + f.x - t.x;
            double b = F[1] + f.y - t.y;
            double c = F[2] + f.z - t.z;

            errptr[i] = (float)(a*a + b*b + c*c);
        }
    }

    // not doing SVD, no degeneracy concerns, can simply return true
    bool checkSubset( InputArray _ms1, InputArray _ms2, int count ) const CV_OVERRIDE
    {
        // voids to suppress compiler warnings
        (void)_ms1;
        (void)_ms2;
        (void)count;
        return true;
    }
};


/*
 * Compute
 *  x     a  b   X    c
 *     =       *    +
 *  y     d  e   Y    f
 *
 *  - every element in _m1 contains (X,Y), which are called source points
 *  - every element in _m2 contains (x,y), which are called destination points
 *  - _model is of size 2x3, which contains
 *    a b c
 *    d e f
 */
class Affine2DEstimatorCallback : public PointSetRegistrator::Callback
{
public:
    int runKernel( InputArray _m1, InputArray _m2, OutputArray _model ) const CV_OVERRIDE
    {
        Mat m1 = _m1.getMat(), m2 = _m2.getMat();
        const Point2f* from = m1.ptr<Point2f>();
        const Point2f* to   = m2.ptr<Point2f>();
        _model.create(2, 3, CV_64F);
        Mat M_mat = _model.getMat();
        double *M = M_mat.ptr<double>();

        // we need 3 points to estimate affine transform
        double x1 = from[0].x;
        double y1 = from[0].y;
        double x2 = from[1].x;
        double y2 = from[1].y;
        double x3 = from[2].x;
        double y3 = from[2].y;

        double X1 = to[0].x;
        double Y1 = to[0].y;
        double X2 = to[1].x;
        double Y2 = to[1].y;
        double X3 = to[2].x;
        double Y3 = to[2].y;

        /*
        We want to solve AX = B

            | x1 y1  1  0  0  0 |
            |  0  0  0 x1 y1  1 |
            | x2 y2  1  0  0  0 |
        A = |  0  0  0 x2 y2  1 |
            | x3 y3  1  0  0  0 |
            |  0  0  0 x3 y3  1 |
        B = (X1, Y1, X2, Y2, X3, Y3).t()
        X = (a, b, c, d, e, f).t()

        As the estimate of (a, b, c) only depends on the Xi, and (d, e, f) only
        depends on the Yi, we do the *trick* to solve each one analytically.

        | X1 |   | x1 y1 1 |   | a |
        | X2 | = | x2 y2 1 | * | b |
        | X3 |   | x3 y3 1 |   | c |

        | Y1 |   | x1 y1 1 |   | d |
        | Y2 | = | x2 y2 1 | * | e |
        | Y3 |   | x3 y3 1 |   | f |
        */

        double d = 1. / ( x1*(y2-y3) + x2*(y3-y1) + x3*(y1-y2) );

        M[0] = d * ( X1*(y2-y3) + X2*(y3-y1) + X3*(y1-y2) );
        M[1] = d * ( X1*(x3-x2) + X2*(x1-x3) + X3*(x2-x1) );
        M[2] = d * ( X1*(x2*y3 - x3*y2) + X2*(x3*y1 - x1*y3) + X3*(x1*y2 - x2*y1) );

        M[3] = d * ( Y1*(y2-y3) + Y2*(y3-y1) + Y3*(y1-y2) );
        M[4] = d * ( Y1*(x3-x2) + Y2*(x1-x3) + Y3*(x2-x1) );
        M[5] = d * ( Y1*(x2*y3 - x3*y2) + Y2*(x3*y1 - x1*y3) + Y3*(x1*y2 - x2*y1) );
        return 1;
    }

    void computeError( InputArray _m1, InputArray _m2, InputArray _model, OutputArray _err ) const CV_OVERRIDE
    {
        Mat m1 = _m1.getMat(), m2 = _m2.getMat(), model = _model.getMat();
        const Point2f* from = m1.ptr<Point2f>();
        const Point2f* to   = m2.ptr<Point2f>();
        const double* F = model.ptr<double>();

        int count = m1.checkVector(2);
        CV_Assert( count > 0 );

        _err.create(count, 1, CV_32F);
        Mat err = _err.getMat();
        float* errptr = err.ptr<float>();
        // transform matrix to floats
        float F0 = (float)F[0], F1 = (float)F[1], F2 = (float)F[2];
        float F3 = (float)F[3], F4 = (float)F[4], F5 = (float)F[5];

        for(int i = 0; i < count; i++ )
        {
            const Point2f& f = from[i];
            const Point2f& t = to[i];

            float a = F0*f.x + F1*f.y + F2 - t.x;
            float b = F3*f.x + F4*f.y + F5 - t.y;

            errptr[i] = a*a + b*b;
        }
    }

    bool checkSubset( InputArray _ms1, InputArray _ms2, int count ) const CV_OVERRIDE
    {
        Mat ms1 = _ms1.getMat();
        Mat ms2 = _ms2.getMat();
        // check collinearity and also check that points are too close
        return !haveCollinearPoints(ms1, count) && !haveCollinearPoints(ms2, count);
    }
};

/*
 * Compute
 *  x    c -s    X    t1
 *    =       *     +
 *  y    s  c    Y    t2
 *
 *  - every element in _m1 contains (X,Y), which are called source points
 *  - every element in _m2 contains (x,y), which are called destination points
 *  - _model is of size 2x3, which contains
 *    c  -s  t1
 *    s   c  t2
 */
class AffinePartial2DEstimatorCallback : public Affine2DEstimatorCallback
{
public:
    int runKernel( InputArray _m1, InputArray _m2, OutputArray _model ) const CV_OVERRIDE
    {
        Mat m1 = _m1.getMat(), m2 = _m2.getMat();
        const Point2f* from = m1.ptr<Point2f>();
        const Point2f* to   = m2.ptr<Point2f>();
        _model.create(2, 3, CV_64F);
        Mat M_mat = _model.getMat();
        double *M = M_mat.ptr<double>();

        // we need only 2 points to estimate transform
        double x1 = from[0].x;
        double y1 = from[0].y;
        double x2 = from[1].x;
        double y2 = from[1].y;

        double X1 = to[0].x;
        double Y1 = to[0].y;
        double X2 = to[1].x;
        double Y2 = to[1].y;

        /*
        we are solving AS = B
            | x1 -y1 1 0 |
            | y1  x1 0 1 |
        A = | x2 -y2 1 0 |
            | y2  x2 0 1 |
        B = (X1, Y1, X2, Y2).t()
        we solve that analytically
        */
        double d = 1./((x1-x2)*(x1-x2) + (y1-y2)*(y1-y2));

        // solution vector
        double S0 = d * ( (X1-X2)*(x1-x2) + (Y1-Y2)*(y1-y2) );
        double S1 = d * ( (Y1-Y2)*(x1-x2) - (X1-X2)*(y1-y2) );
        double S2 = d * ( (Y1-Y2)*(x1*y2 - x2*y1) - (X1*y2 - X2*y1)*(y1-y2) - (X1*x2 - X2*x1)*(x1-x2) );
        double S3 = d * (-(X1-X2)*(x1*y2 - x2*y1) - (Y1*x2 - Y2*x1)*(x1-x2) - (Y1*y2 - Y2*y1)*(y1-y2) );

        // set model, rotation part is antisymmetric
        M[0] = M[4] = S0;
        M[1] = -S1;
        M[2] = S2;
        M[3] = S1;
        M[5] = S3;
        return 1;
    }
};

class Affine2DRefineCallback : public LMSolver::Callback
{
public:
    Affine2DRefineCallback(InputArray _src, InputArray _dst)
    {
        src = _src.getMat();
        dst = _dst.getMat();
    }

    bool compute(InputArray _param, OutputArray _err, OutputArray _Jac) const CV_OVERRIDE
    {
        int i, count = src.checkVector(2);
        Mat param = _param.getMat();
        _err.create(count*2, 1, CV_64F);
        Mat err = _err.getMat(), J;
        if( _Jac.needed())
        {
            _Jac.create(count*2, param.rows, CV_64F);
            J = _Jac.getMat();
            CV_Assert( J.isContinuous() && J.cols == 6 );
        }

        const Point2f* M = src.ptr<Point2f>();
        const Point2f* m = dst.ptr<Point2f>();
        const double* h = param.ptr<double>();
        double* errptr = err.ptr<double>();
        double* Jptr = J.data ? J.ptr<double>() : 0;

        for( i = 0; i < count; i++ )
        {
            double Mx = M[i].x, My = M[i].y;
            double xi = h[0]*Mx + h[1]*My + h[2];
            double yi = h[3]*Mx + h[4]*My + h[5];
            errptr[i*2] = xi - m[i].x;
            errptr[i*2+1] = yi - m[i].y;

            /*
            Jacobian should be:
                {x, y, 1, 0, 0, 0}
                {0, 0, 0, x, y, 1}
            */
            if( Jptr )
            {
                Jptr[0] = Mx; Jptr[1] = My; Jptr[2] = 1.;
                Jptr[3] = Jptr[4] = Jptr[5] = 0.;
                Jptr[6] = Jptr[7] = Jptr[8] = 0.;
                Jptr[9] = Mx; Jptr[10] = My; Jptr[11] = 1.;

                Jptr += 6*2;
            }
        }

        return true;
    }

    Mat src, dst;
};

class AffinePartial2DRefineCallback : public LMSolver::Callback
{
public:
    AffinePartial2DRefineCallback(InputArray _src, InputArray _dst)
    {
        src = _src.getMat();
        dst = _dst.getMat();
    }

    bool compute(InputArray _param, OutputArray _err, OutputArray _Jac) const CV_OVERRIDE
    {
        int i, count = src.checkVector(2);
        Mat param = _param.getMat();
        _err.create(count*2, 1, CV_64F);
        Mat err = _err.getMat(), J;
        if( _Jac.needed())
        {
            _Jac.create(count*2, param.rows, CV_64F);
            J = _Jac.getMat();
            CV_Assert( J.isContinuous() && J.cols == 4 );
        }

        const Point2f* M = src.ptr<Point2f>();
        const Point2f* m = dst.ptr<Point2f>();
        const double* h = param.ptr<double>();
        double* errptr = err.ptr<double>();
        double* Jptr = J.data ? J.ptr<double>() : 0;

        for( i = 0; i < count; i++ )
        {
            double Mx = M[i].x, My = M[i].y;
            double xi = h[0]*Mx - h[1]*My + h[2];
            double yi = h[1]*Mx + h[0]*My + h[3];
            errptr[i*2] = xi - m[i].x;
            errptr[i*2+1] = yi - m[i].y;

            /*
            Jacobian should be:
                {x, -y, 1, 0}
                {y,  x, 0, 1}
            */
            if( Jptr )
            {
                Jptr[0] = Mx; Jptr[1] = -My; Jptr[2] = 1.; Jptr[3] = 0.;
                Jptr[4] = My; Jptr[5] =  Mx; Jptr[6] = 0.; Jptr[7] = 1.;

                Jptr += 4*2;
            }
        }

        return true;
    }

    Mat src, dst;
};

int estimateAffine3D(InputArray _from, InputArray _to,
                     OutputArray _out, OutputArray _inliers,
                     double ransacThreshold, double confidence)
{
    CV_INSTRUMENT_REGION();

    Mat from = _from.getMat(), to = _to.getMat();
    int count = from.checkVector(3);

    CV_Assert( count >= 0 && to.checkVector(3) == count );

    Mat dFrom, dTo;
    from.convertTo(dFrom, CV_32F);
    to.convertTo(dTo, CV_32F);
    dFrom = dFrom.reshape(3, count);
    dTo = dTo.reshape(3, count);

    const double epsilon = DBL_EPSILON;
    ransacThreshold = ransacThreshold <= 0 ? 3 : ransacThreshold;
    confidence = (confidence < epsilon) ? 0.99 : (confidence > 1 - epsilon) ? 0.99 : confidence;

    return createRANSACPointSetRegistrator(makePtr<Affine3DEstimatorCallback>(), 4, ransacThreshold, confidence)->run(dFrom, dTo, _out, _inliers);
}

int estimateTranslation3D(InputArray _from, InputArray _to,
                          OutputArray _out, OutputArray _inliers,
                          double ransacThreshold, double confidence)
{
    CV_INSTRUMENT_REGION();

    Mat from = _from.getMat(), to = _to.getMat();
    int count = from.checkVector(3);

    CV_Assert( count >= 0 && to.checkVector(3) == count );

    Mat dFrom, dTo;
    from.convertTo(dFrom, CV_32F);
    to.convertTo(dTo, CV_32F);
    dFrom = dFrom.reshape(3, count);
    dTo = dTo.reshape(3, count);

    const double epsilon = DBL_EPSILON;
    ransacThreshold = ransacThreshold <= 0 ? 3 : ransacThreshold;
    confidence = (confidence < epsilon) ? 0.99 : (confidence > 1 - epsilon) ? 0.99 : confidence;

    return createRANSACPointSetRegistrator(makePtr<Translation3DEstimatorCallback>(), 4, ransacThreshold, confidence)->run(dFrom, dTo, _out, _inliers);
}

Mat estimateAffine2D(InputArray _from, InputArray _to, OutputArray _inliers,
                     const int method, const double ransacReprojThreshold,
                     const size_t maxIters, const double confidence,
                     const size_t refineIters)
{
    Mat from = _from.getMat(), to = _to.getMat();
    int count = from.checkVector(2);
    bool result = false;
    Mat H;

    CV_Assert( count >= 0 && to.checkVector(2) == count );

    if (from.type() != CV_32FC2 || to.type() != CV_32FC2)
    {
        Mat tmp1, tmp2;
        from.convertTo(tmp1, CV_32FC2);
        from = tmp1;
        to.convertTo(tmp2, CV_32FC2);
        to = tmp2;
    }
    else
    {
        // avoid changing of inputs in compressElems() call
        from = from.clone();
        to = to.clone();
    }

    // convert to N x 1 vectors
    from = from.reshape(2, count);
    to = to.reshape(2, count);

    Mat inliers;
    if(_inliers.needed())
    {
        _inliers.create(count, 1, CV_8U, -1, true);
        inliers = _inliers.getMat();
    }

    // run robust method
    Ptr<PointSetRegistrator::Callback> cb = makePtr<Affine2DEstimatorCallback>();
    if( method == RANSAC )
        result = createRANSACPointSetRegistrator(cb, 3, ransacReprojThreshold, confidence, static_cast<int>(maxIters))->run(from, to, H, inliers);
    else if( method == LMEDS )
        result = createLMeDSPointSetRegistrator(cb, 3, confidence, static_cast<int>(maxIters))->run(from, to, H, inliers);
    else
        CV_Error(Error::StsBadArg, "Unknown or unsupported robust estimation method");

    if(result && count > 3 && refineIters)
    {
        // reorder to start with inliers
        compressElems(from.ptr<Point2f>(), inliers.ptr<uchar>(), 1, count);
        int inliers_count = compressElems(to.ptr<Point2f>(), inliers.ptr<uchar>(), 1, count);
        if(inliers_count > 0)
        {
            Mat src = from.rowRange(0, inliers_count);
            Mat dst = to.rowRange(0, inliers_count);
            Mat Hvec = H.reshape(1, 6);
            LMSolver::create(makePtr<Affine2DRefineCallback>(src, dst), static_cast<int>(refineIters))->run(Hvec);
        }
    }

    if (!result)
    {
        H.release();
        if(_inliers.needed())
        {
            inliers = Mat::zeros(count, 1, CV_8U);
            inliers.copyTo(_inliers);
        }
    }

    return H;
}

Mat estimateAffinePartial2D(InputArray _from, InputArray _to, OutputArray _inliers,
                            const int method, const double ransacReprojThreshold,
                            const size_t maxIters, const double confidence,
                            const size_t refineIters)
{
    Mat from = _from.getMat(), to = _to.getMat();
    const int count = from.checkVector(2);
    bool result = false;
    Mat H;

    CV_Assert( count >= 0 && to.checkVector(2) == count );

    if (from.type() != CV_32FC2 || to.type() != CV_32FC2)
    {
        Mat tmp1, tmp2;
        from.convertTo(tmp1, CV_32FC2);
        from = tmp1;
        to.convertTo(tmp2, CV_32FC2);
        to = tmp2;
    }
    else
    {
        // avoid changing of inputs in compressElems() call
        from = from.clone();
        to = to.clone();
    }

    // convert to N x 1 vectors
    from = from.reshape(2, count);
    to = to.reshape(2, count);

    Mat inliers;
    if(_inliers.needed())
    {
        _inliers.create(count, 1, CV_8U, -1, true);
        inliers = _inliers.getMat();
    }

    // run robust estimation
    Ptr<PointSetRegistrator::Callback> cb = makePtr<AffinePartial2DEstimatorCallback>();
    if( method == RANSAC )
        result = createRANSACPointSetRegistrator(cb, 2, ransacReprojThreshold, confidence, static_cast<int>(maxIters))->run(from, to, H, inliers);
    else if( method == LMEDS )
        result = createLMeDSPointSetRegistrator(cb, 2, confidence, static_cast<int>(maxIters))->run(from, to, H, inliers);
    else
        CV_Error(Error::StsBadArg, "Unknown or unsupported robust estimation method");

    if(result && count > 2 && refineIters)
    {
        // reorder to start with inliers
        compressElems(from.ptr<Point2f>(), inliers.ptr<uchar>(), 1, count);
        int inliers_count = compressElems(to.ptr<Point2f>(), inliers.ptr<uchar>(), 1, count);
        if(inliers_count > 0)
        {
            Mat src = from.rowRange(0, inliers_count);
            Mat dst = to.rowRange(0, inliers_count);
            // H is
            //     a -b tx
            //     b  a ty
            // Hvec model for LevMarq is
            //     (a, b, tx, ty)
            double *Hptr = H.ptr<double>();
            double Hvec_buf[4] = {Hptr[0], Hptr[3], Hptr[2], Hptr[5]};
            Mat Hvec (4, 1, CV_64F, Hvec_buf);
            LMSolver::create(makePtr<AffinePartial2DRefineCallback>(src, dst), static_cast<int>(refineIters))->run(Hvec);
            // update H with refined parameters
            Hptr[0] = Hptr[4] = Hvec_buf[0];
            Hptr[1] = -Hvec_buf[1];
            Hptr[2] = Hvec_buf[2];
            Hptr[3] = Hvec_buf[1];
            Hptr[5] = Hvec_buf[3];
        }
    }

    if (!result)
    {
        H.release();
        if(_inliers.needed())
        {
            inliers = Mat::zeros(count, 1, CV_8U);
            inliers.copyTo(_inliers);
        }
    }

    return H;
}

} // namespace cv
