void HomogeneousPoint3fIntegralImage::compute(const Eigen::MatrixXi &indices, const HomogeneousPoint3fVector &points) {
  if (cols() != indices.cols() || rows() != indices.rows())
    resize(indices.rows(), indices.cols());
  clear();
  
  HomogeneousPoint3fAccumulator *acc = data();
  const int *pointIndex = indices.data();
  int s = rows() * cols();
  // fill the accumulators with the points
  for (int i=0; i<s; i++, acc++, pointIndex++){
    if (*pointIndex<0)
      continue;
    const HomogeneousPoint3f& point = points[*pointIndex];
    acc->operator += (point);
  }

  // fill by column
  #pragma omp parallel for
  for (int c=0; c<cols(); c++){
    for (int r=1; r<rows(); r++){
      coeffRef(r,c) += coeffRef(r-1,c);
    }
  }

  // fill by row
  #pragma omp parallel for
  for (int r=0; r<rows(); r++){
    for (int c=1; c<cols(); c++){
      coeffRef(r,c) += coeffRef(r,c-1);
    }
  }
}
/*!
*  \brief      Convert cv::Mat to integer Eigen matrix
*  \author     Sascha Kaden
*  \param[in]  image
*  \param[out] Eigen matrix
*  \date       2016-12-18
*/
cv::Mat eigenToCV(Eigen::MatrixXi eigenMat) {
    cv::Mat cvMat(eigenMat.rows(), eigenMat.cols(), CV_32SC1, eigenMat.data());

    if (Eigen::RowMajorBit)
        cv::transpose(cvMat, cvMat);

    cv::Mat dst;
    cvMat.convertTo(dst, CV_8UC1);
    cv::cvtColor(dst, dst, CV_GRAY2BGR);

    return dst;
}
Exemple #3
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void parse_rhs(
  const int nrhs, 
  const mxArray *prhs[], 
  Eigen::MatrixXd & V,
  Eigen::MatrixXi & F,
  Eigen::MatrixXd & P,
  Eigen::MatrixXd & N,
  int & num_samples)
{
  using namespace std;
  if(nrhs < 5)
  {
    mexErrMsgTxt("nrhs < 5");
  }

  const int dim = mxGetN(prhs[0]);
  if(dim != 3)
  {
    mexErrMsgTxt("Mesh vertex list must be #V by 3 list of vertex positions");
  }
  if(dim != (int)mxGetN(prhs[1]))
  {
   mexErrMsgTxt("Mesh facet size must be 3");
  }
  if(mxGetN(prhs[2]) != dim)
  {
    mexErrMsgTxt("Point list must be #P by 3 list of origin locations");
  }
  if(mxGetN(prhs[3]) != dim)
  {
    mexErrMsgTxt("Normal list must be #P by 3 list of origin normals");
  }
  if(mxGetN(prhs[4]) != 1 || mxGetM(prhs[4]) != 1)
  {
    mexErrMsgTxt("Number of samples must be scalar.");
  }


  V.resize(mxGetM(prhs[0]),mxGetN(prhs[0]));
  copy(mxGetPr(prhs[0]),mxGetPr(prhs[0])+V.size(),V.data());
  F.resize(mxGetM(prhs[1]),mxGetN(prhs[1]));
  copy(mxGetPr(prhs[1]),mxGetPr(prhs[1])+F.size(),F.data());
  F.array() -= 1;
  P.resize(mxGetM(prhs[2]),mxGetN(prhs[2]));
  copy(mxGetPr(prhs[2]),mxGetPr(prhs[2])+P.size(),P.data());
  N.resize(mxGetM(prhs[3]),mxGetN(prhs[3]));
  copy(mxGetPr(prhs[3]),mxGetPr(prhs[3])+N.size(),N.data());
  if(*mxGetPr(prhs[4]) != (int)*mxGetPr(prhs[4]))
  {
    mexErrMsgTxt("Number of samples should be non negative integer.");
  }
  num_samples = (int) *mxGetPr(prhs[4]);
}
Exemple #4
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// IF THIS IS EVER TEMPLATED BE SURE THAT V IS COLMAJOR
IGL_INLINE void igl::winding_number(
    const Eigen::MatrixXd & V,
    const Eigen::MatrixXi & F,
    const Eigen::MatrixXd & O,
    Eigen::VectorXd & W)
{
    using namespace Eigen;
    // make room for output
    W.resize(O.rows(),1);
    switch(F.cols())
    {
    case 2:
        return winding_number_2(
                   V.data(),
                   V.rows(),
                   F.data(),
                   F.rows(),
                   O.data(),
                   O.rows(),
                   W.data());
    case 3:
    {
        WindingNumberAABB<Vector3d> hier(V,F);
        hier.grow();
        // loop over origins
        const int no = O.rows();
        #   pragma omp parallel for if (no>IGL_WINDING_NUMBER_OMP_MIN_VALUE)
        for(int o = 0; o<no; o++)
        {
            Vector3d p = O.row(o);
            W(o) = hier.winding_number(p);
        }
        break;
    }
    default:
        assert(false && "Bad simplex size");
        break;
    }
}