void LaplacianOperator::computeLaplacianOperator( Eigen::SparseMatrix<double>& laplacianOperator )
{
	laplacianOperator.resize(mMeshVertexCount,mMeshVertexCount);
	laplacianOperator.reserve(Eigen::VectorXi::Constant(mMeshVertexCount,10));
	for (int i = 0; i < mMeshVertexCount; i++)
	{
		/* 如果第i个点没有邻接点,即它是一个孤立的点,那么它的laplacian坐标为0 */
		if( adjacentMatrix.innerVector(i).nonZeros() == 0)
		{
			laplacianOperator.insert(i,i) = 0;
			continue;
		}
		laplacianOperator.insert(i,i) = 1;
#ifdef MY_DEBUG
		int adjCount = 0;
#endif		
		for (Eigen::SparseMatrix<double>::InnerIterator it(adjacentMatrix,i); it; it++)
		{
			if(i != it.row())
			{
				laplacianOperator.insert(i,it.row()) = -1/degreeMatrix(i);				
#ifdef MY_DEBUG
			adjCount++;
			if(adjCount >= 10)
				printf("InnerVector size should expand! CurrentMax:%d.\n",adjCount);
#endif
			}
		}
	}
}
Beispiel #2
0
IGL_INLINE void igl::sparse(
  const IndexVector & I,
  const IndexVector & J,
  const ValueVector & V,
  const size_t m,
  const size_t n,
  Eigen::SparseMatrix<T>& X)
{
  using namespace std;
  using namespace Eigen;
  assert((int)I.maxCoeff() < (int)m);
  assert((int)I.minCoeff() >= 0);
  assert((int)J.maxCoeff() < (int)n);
  assert((int)J.minCoeff() >= 0);
  assert(I.size() == J.size());
  assert(J.size() == V.size());
  // Really we just need .size() to be the same, but this is safer
  assert(I.rows() == J.rows());
  assert(J.rows() == V.rows());
  assert(I.cols() == J.cols());
  assert(J.cols() == V.cols());

  vector<Triplet<T> > IJV;
  IJV.reserve(I.size());
  for(int x = 0;x<I.size();x++)
  {
    IJV.push_back(Triplet<T >(I(x),J(x),V(x)));
  }
  X.resize(m,n);
  X.setFromTriplets(IJV.begin(),IJV.end());
}
Beispiel #3
0
ZSparseMatrix Assembler2D::getDisplacementStrainMatrix() {
    typedef Eigen::Triplet<double> T;
    std::vector<T> triplets;

    for (size_t i=0; i<m_mesh->getNbrElements(); i++) {
        Eigen::MatrixXd dN = m_DN[i];
        VectorI idx = m_mesh->getElement(i);
        assert(idx.size() == 3);
        double V = m_mesh->getElementVolume(i);

        // e_xx
        size_t row = i * 3;
        for (size_t k=0; k<3; k++) {
            triplets.push_back(T(row, idx[k]*2, dN(k,0)));
        }

        // e_yy
        row++;
        for (size_t k=0; k<3; k++) {
            triplets.push_back(T(row, idx[k]*2+1, dN(k,1)));
        }

        // e_xy
        row++;
        for (size_t k=0; k<3; k++) {
            triplets.push_back(T(row, idx[k]*2  , dN(k,1) / 2.0));
            triplets.push_back(T(row, idx[k]*2+1, dN(k,0) / 2.0));
        }
    }

    Eigen::SparseMatrix<double> B = Eigen::SparseMatrix<double>(3*m_mesh->getNbrElements(), 2*m_mesh->getNbrNodes());
    B.setFromTriplets(triplets.begin(), triplets.end());
    return ZSparseMatrix(B);
}
Beispiel #4
0
void SetConstraints(Eigen::SparseMatrix<float>::InnerIterator& it, int index)
{
	if (it.row() == index || it.col() == index)
	{
		it.valueRef() = it.row() == it.col() ? 1.0f : 0.0f;
	}
}
Beispiel #5
0
void ProbitNoise::evalModel(Eigen::SparseMatrix<double> & Ytest, const int n, Eigen::VectorXd & predictions, Eigen::VectorXd & predictions_var, const Eigen::MatrixXd &cols, const Eigen::MatrixXd &rows, double mean_rating) {
  const unsigned N = Ytest.nonZeros();
  Eigen::VectorXd pred(N);
  Eigen::VectorXd test(N);

// #pragma omp parallel for schedule(dynamic,8) reduction(+:se, se_avg) <- dark magic :)
  for (int k = 0; k < Ytest.outerSize(); ++k) {
    int idx = Ytest.outerIndexPtr()[k];
    for (Eigen::SparseMatrix<double>::InnerIterator it(Ytest,k); it; ++it) {
     pred[idx] = nCDF(cols.col(it.col()).dot(rows.col(it.row())));
     test[idx] = it.value();

      // https://en.wikipedia.org/wiki/Algorithms_for_calculating_variance#Online_algorithm
      double pred_avg;
      if (n == 0) {
        pred_avg = pred[idx];
      } else {
        double delta = pred[idx] - predictions[idx];
        pred_avg = (predictions[idx] + delta / (n + 1));
        predictions_var[idx] += delta * (pred[idx] - pred_avg);
      }
      predictions[idx++] = pred_avg;

   }
  }
  auc_test_onesample = auc(pred,test);
  auc_test = auc(predictions, test);
}
Beispiel #6
0
ZSparseMatrix Assembler2D::getLaplacianMatrix() {
    typedef Eigen::Triplet<double> T;
    std::vector<T> triplets;

    for (size_t i=0; i<m_mesh->getNbrElements(); ++i)
    {
        VectorI idx = m_mesh->getElement(i);
        assert(idx.size() == 3);

        Eigen::MatrixXd& dN = m_DN[i];

        // Small strain-displacement matrix
        //
        Eigen::MatrixXd B(2,3);
        B << dN(0,0), dN(1,0), dN(2,0),
        dN(0,1), dN(1,1), dN(2,1);

        Eigen::MatrixXd k_el = B.transpose() * B * m_mesh->getElementVolume(i);

        for (size_t j=0; j<3; ++j)
            for (size_t k=0; k<3; ++k)
                triplets.push_back(T(idx[j], idx[k], k_el(j,k)));
    }

    Eigen::SparseMatrix<double> L = Eigen::SparseMatrix<double>(m_mesh->getNbrNodes(), m_mesh->getNbrNodes());
    L.setFromTriplets(triplets.begin(), triplets.end());
    return ZSparseMatrix(L);
}
void igl::crouzeix_raviart_massmatrix(
    const Eigen::PlainObjectBase<DerivedV> & V, 
    const Eigen::PlainObjectBase<DerivedF> & F, 
    const Eigen::PlainObjectBase<DerivedE> & E,
    const Eigen::PlainObjectBase<DerivedEMAP> & EMAP,
    Eigen::SparseMatrix<MT> & M)
{
  using namespace Eigen;
  using namespace std;
  assert(F.cols() == 3);
  // Mesh should be edge-manifold
  assert(is_edge_manifold(F));
  // number of elements (triangles)
  int m = F.rows();
  // Get triangle areas
  VectorXd TA;
  doublearea(V,F,TA);
  vector<Triplet<MT> > MIJV(3*m);
  for(int f = 0;f<m;f++)
  {
    for(int c = 0;c<3;c++)
    {
      MIJV[f+m*c] = Triplet<MT>(EMAP(f+m*c),EMAP(f+m*c),TA(f)*0.5);
    }
  }
  M.resize(E.rows(),E.rows());
  M.setFromTriplets(MIJV.begin(),MIJV.end());
}
Beispiel #8
0
IGL_INLINE void igl::find(
  const Eigen::SparseMatrix<T>& X,
  Eigen::DenseBase<DerivedI> & I,
  Eigen::DenseBase<DerivedJ> & J,
  Eigen::DenseBase<DerivedV> & V)
{
  // Resize outputs to fit nonzeros
  I.derived().resize(X.nonZeros(),1);
  J.derived().resize(X.nonZeros(),1);
  V.derived().resize(X.nonZeros(),1);

  int i = 0;
  // Iterate over outside
  for(int k=0; k<X.outerSize(); ++k)
  {
    // Iterate over inside
    for(typename Eigen::SparseMatrix<T>::InnerIterator it (X,k); it; ++it)
    {
      V(i) = it.value();
      I(i) = it.row();
      J(i) = it.col();
      i++;
    }
  }
}
void LTransform::Create_spMat_U(Eigen::SparseMatrix<double> &spMat_U){
    //*****************************
    //2015-06-29 TYPE=Notes
    //*****************************
    //求解笛卡尔坐标;2.构建控制点矩阵spMat_U;
    //*****************************
    //spMat_U=spMat_V;

    //*****************************
    qDebug() <<"START:spMat_U.insert"<< endl;
    for(int i=0;i<LMT_point.size();i++){

        spMat_U.insert(LMT_point[i].index,0)=LMT_point[i].X;
        spMat_U.insert(LMT_point[i].index,1)=LMT_point[i].Y;
        spMat_U.insert(LMT_point[i].index,2)=LMT_point[i].Z;

    }


    for (int k=0; k<spMat_V.outerSize(); ++k)
        for (Eigen::SparseMatrix<double>::InnerIterator it(spMat_V,k); it; ++it){

            if(!objMesh.is_limitP(LMT_point,it.row())){
                spMat_U.insert(it.row(),it.col())=it.value();
            }

        }
    qDebug() <<"END:spMat_U.insert"<< endl;

}//控制点坐标矩阵;
Beispiel #10
0
IGL_INLINE void igl::min(
  const Eigen::SparseMatrix<AType> & A,
  const int dim,
  Eigen::PlainObjectBase<DerivedB> & B,
  Eigen::PlainObjectBase<DerivedI> & I)
{
  const int n = A.cols();
  const int m = A.rows();
  B.resize(dim==1?n:m);
  B.setConstant(std::numeric_limits<typename DerivedB::Scalar>::max());
  I.resize(dim==1?n:m);
  for_each(A,[&B,&I,&dim](int i, int j,const typename DerivedB::Scalar v)
    {
      if(dim == 2)
      {
        std::swap(i,j);
      }
      // Coded as if dim == 1, assuming swap for dim == 2
      if(v < B(j))
      {
        B(j) = v;
        I(j) = i;
      }
    });
  Eigen::VectorXi Z;
  find_zero(A,dim,Z);
  for(int j = 0;j<I.size();j++)
  {
    if(Z(j) != (dim==1?m:n) && 0 < B(j))
    {
      B(j) = 0;
      I(j) = Z(j);
    }
  }
}
Beispiel #11
0
IGL_INLINE void igl::PolyVectorFieldFinder<DerivedV, DerivedF>::computeCoefficientLaplacian(int n, Eigen::SparseMatrix<std::complex<typename DerivedV::Scalar> > &D)
{
  std::vector<Eigen::Triplet<std::complex<typename DerivedV::Scalar> >> tripletList;

  // For every non-border edge
  for (unsigned eid=0; eid<numE; ++eid)
  {
    if (!isBorderEdge[eid])
    {
      int fid0 = E2F(eid,0);
      int fid1 = E2F(eid,1);

      tripletList.push_back(Eigen::Triplet<std::complex<typename DerivedV::Scalar> >(fid0,
                                           fid0,
                                           std::complex<typename DerivedV::Scalar>(1.)));
      tripletList.push_back(Eigen::Triplet<std::complex<typename DerivedV::Scalar> >(fid1,
                                           fid1,
                                           std::complex<typename DerivedV::Scalar>(1.)));
      tripletList.push_back(Eigen::Triplet<std::complex<typename DerivedV::Scalar> >(fid0,
                                           fid1,
                                                                                     -1.*std::polar(1.,-1.*n*K[eid])));
      tripletList.push_back(Eigen::Triplet<std::complex<typename DerivedV::Scalar> >(fid1,
                                           fid0,
                                                                                     -1.*std::polar(1.,1.*n*K[eid])));

    }
  }
  D.resize(numF,numF);
  D.setFromTriplets(tripletList.begin(), tripletList.end());


}
Beispiel #12
0
IGL_INLINE void igl::in_element(
  const Eigen::PlainObjectBase<DerivedV> & V,
  const Eigen::MatrixXi & Ele,
  const Eigen::PlainObjectBase<DerivedQ> & Q,
  const AABB<DerivedV,DIM> & aabb,
  Eigen::SparseMatrix<Scalar> & I)
{
  using namespace std;
  using namespace Eigen;
  using namespace igl;
  const int Qr = Q.rows();
  std::vector<Triplet<Scalar> > IJV;
  IJV.reserve(Qr);
#pragma omp parallel for if (Qr>10000)
  for(int e = 0;e<Qr;e++)
  {
    // find all
    const auto R = aabb.find(V,Ele,Q.row(e),false);
    for(const auto r : R)
    {
#pragma omp critical
      IJV.push_back(Triplet<Scalar>(e,r,1));
    }
  }
  I.resize(Qr,Ele.rows());
  I.setFromTriplets(IJV.begin(),IJV.end());
}
Beispiel #13
0
IGL_INLINE void igl::in_element(
  const Eigen::MatrixXd & V,
  const Eigen::MatrixXi & Ele,
  const Eigen::MatrixXd & Q,
  const InElementAABB & aabb,
  Eigen::SparseMatrix<double> & I)
{
  using namespace std;
  using namespace Eigen;
  using namespace igl;
  const int Qr = Q.rows();
  std::vector<Triplet<double> > IJV;
  IJV.reserve(Qr);
#pragma omp parallel for
  for(int e = 0;e<Qr;e++)
  {
    // find all
    const auto R = aabb.find(V,Ele,Q.row(e),false);
    for(const auto r : R)
    {
#pragma omp critical
      IJV.push_back(Triplet<double>(e,r,1));
    }
  }
  I.resize(Qr,Ele.rows());
  I.setFromTriplets(IJV.begin(),IJV.end());
}
Beispiel #14
0
IGL_INLINE void igl::slice_into(
  const Eigen::SparseMatrix<T>& X,
  const Eigen::Matrix<int,Eigen::Dynamic,1> & R,
  const Eigen::Matrix<int,Eigen::Dynamic,1> & C,
  Eigen::SparseMatrix<T>& Y)
{

  int xm = X.rows();
  int xn = X.cols();
  assert(R.size() == xm);
  assert(C.size() == xn);
#ifndef NDEBUG
  int ym = Y.size();
  int yn = Y.size();
  assert(R.minCoeff() >= 0);
  assert(R.maxCoeff() < ym);
  assert(C.minCoeff() >= 0);
  assert(C.maxCoeff() < yn);
#endif

  // create temporary dynamic sparse matrix
  Eigen::DynamicSparseMatrix<T, Eigen::RowMajor>  dyn_Y(Y);
  // Iterate over outside
  for(int k=0; k<X.outerSize(); ++k)
  {
    // Iterate over inside
    for(typename Eigen::SparseMatrix<T>::InnerIterator it (X,k); it; ++it)
    {
      dyn_Y.coeffRef(R(it.row()),C(it.col())) = it.value();
    }
  }
  Y = Eigen::SparseMatrix<T>(dyn_Y);
}
void place::erodeSparse(const Eigen::SparseMatrix<double> &src,
                        Eigen::SparseMatrix<double> &dst) {
  dst = Eigen::SparseMatrix<double>(src.rows(), src.cols());
  std::vector<Eigen::Triplet<double>> tripletList;
  Eigen::MatrixXd srcNS = Eigen::MatrixXd(src);

  for (int i = 0; i < srcNS.cols(); ++i) {
    for (int j = 0; j < srcNS.rows(); ++j) {
      double value = 0.0;
      for (int k = -1; k < 1; ++k) {
        for (int l = -1; l < 1; ++l) {
          if (i + k < 0 || i + k >= srcNS.cols() || j + l < 0 ||
              j + l >= srcNS.rows())
            continue;
          else
            value = std::max(value, srcNS(j + l, i + k));
        }
      }

      if (value != 0)
        tripletList.push_back(Eigen::Triplet<double>(j, i, value));
    }
  }
  dst.setFromTriplets(tripletList.begin(), tripletList.end());
}
Beispiel #16
0
  // fmap case
  void create_matrix(const paracel::list_type<paracel::str_type> & linelst,
                     Eigen::SparseMatrix<double, Eigen::RowMajor> & blk_mtx,
                     paracel::dict_type<size_t, paracel::str_type> & rm, 
                     paracel::dict_type<size_t, paracel::str_type> & cm,
                     paracel::dict_type<size_t, int> & dm,
                     paracel::dict_type<size_t, int> & col_dm) {

    paracel::scheduler scheduler(m_comm, pattern, mix); // TODO
    // hash lines into slotslst
    auto result = scheduler.lines_organize(linelst, parserfunc);
    std::cout << "procs " << m_comm.get_rank() << " slotslst generated" << std::endl;
    m_comm.sync();
    // alltoall exchange
    auto stf = scheduler.exchange(result);
    std::cout << "procs " << m_comm.get_rank() << " get desirable lines" << std::endl;
    m_comm.sync();
    // mapping inds to ids, get rmap, cmap, std_new...
    paracel::list_type<std::tuple<size_t, size_t, double> > stf_new;
    scheduler.index_mapping(stf, stf_new, rm, cm, dm, col_dm);
    std::cout << "procs " << m_comm.get_rank() << " index mapping" << std::endl;
    // create block sparse matrix
    paracel::list_type<eigen_triple> nonzero_tpls;
    for(auto & tpl : stf_new) {
      nonzero_tpls.push_back(eigen_triple(std::get<0>(tpl), std::get<1>(tpl), std::get<2>(tpl)));
    }
    blk_mtx.resize(rm.size(), cm.size());
    blk_mtx.setFromTriplets(nonzero_tpls.begin(), nonzero_tpls.end());
  }
Beispiel #17
0
matrix<Type> invertSparseMatrix(Eigen::SparseMatrix<Type> A){
  matrix<Type> I(A.rows(),A.cols());
  I.setIdentity();
  Eigen::SimplicialLDLT< Eigen::SparseMatrix<Type> > ldlt(A);
  matrix<Type> ans = ldlt.solve(I);
  return ans;
}
// inserts the sparse matrix 'ins' into the sparse matrix 'original' in the place given by 'row' and 'col' integers
void insertSparseBlock(const Eigen::SparseMatrix<Scalar>& ins, Eigen::SparseMatrix<Scalar>& original, const unsigned int& row, const unsigned int& col)
{
  for (int k=0; k<ins.outerSize(); ++k)
    for (Eigen::SparseMatrix<Scalar>::InnerIterator iti(ins,k); iti; ++iti)
      original.coeffRef(iti.row() + row, iti.col() + col) = iti.value();

  original.makeCompressed();
}
Beispiel #19
0
void CodeAtlas::FuzzyDependBuilder::buildChildDepend( QMultiHash<QString, ChildPack>& childList , 
													 Eigen::SparseMatrix<double>& vtxEdgeMat,
													 Eigen::VectorXd&             edgeWeightVec,
													 QList<FuzzyDependAttr::DependPair>& dependPair)
{
	QStringList codeList;
	QVector<ChildPack*> childPackPtr;
	for (QMultiHash<QString, ChildPack>::Iterator pChild = childList.begin();
		pChild != childList.end(); ++pChild)
	{
		codeList.push_back(pChild.value().m_code);
		childPackPtr.push_back(&pChild.value());
	}

	std::vector<Triplet> tripletArray;
	QVector<double>		 edgeWeightArray;

	// add dependency edges between child nodes
	int ithSrc = 0;
	for (QMultiHash<QString, ChildPack>::Iterator pChild = childList.begin();
		pChild != childList.end(); ++pChild, ++ithSrc)
	{
		// for each child, find number of occurrences of this child's name
		ChildPack& srcChild = pChild.value();
		const QString& srcName = pChild.key();
		QVector<int> occurence;
		WordExtractor::findOccurrence(srcName, codeList, occurence);

		for (int ithTar = 0; ithTar < childPackPtr.size(); ++ithTar)
		{
			int nOccur = occurence[ithTar];
			if (nOccur == 0 || ithTar == ithSrc)
				continue;

			ChildPack& tarChild = *childPackPtr[ithTar];

			SymbolEdge::Ptr pEdge = SymbolTree::getOrAddEdge(srcChild.m_pNode, tarChild.m_pNode, SymbolEdge::EDGE_FUZZY_DEPEND);
			pEdge->clear();
			pEdge->strength() = nOccur;

			int nEdge = tripletArray.size()/2;
			tripletArray.push_back(Triplet(srcChild.m_index, nEdge ,1.0));
			tripletArray.push_back(Triplet(tarChild.m_index, nEdge ,-1.0));

			edgeWeightArray.push_back(nOccur);
			dependPair.push_back(FuzzyDependAttr::DependPair(srcChild.m_pNode, tarChild.m_pNode, nOccur));
		}
	}

	if (int nEdges = tripletArray.size()/2)
	{
		vtxEdgeMat.resize(childList.size(),nEdges);
		vtxEdgeMat.setFromTriplets(tripletArray.begin(), tripletArray.end());
		edgeWeightVec.resize(nEdges);
		memcpy(edgeWeightVec.data(), edgeWeightArray.data(), sizeof(double)* nEdges);
	}
}
Beispiel #20
0
Mat::Mat(vector<string> _row_names, vector<string> _col_names,
	Eigen::SparseMatrix<double> _matrix,MatType _mattype)
{
	row_names = _row_names;
	col_names = _col_names;
	assert(row_names.size() == _matrix.rows());
	assert(col_names.size() == _matrix.cols());
	matrix = _matrix;
	mattype = _mattype;
}
	void UnknownVars::Solve(const AAndBVars& aAndBVars)
	{
		// solve Ax = b using UmfPack:
		Eigen::SparseMatrix<double> A = aAndBVars.GetA();
		A.transpose();
		Eigen::SparseLU<Eigen::SparseMatrix<double>,Eigen::UmfPack> lu_of_A(A);
		wxASSERT(lu_of_A.succeeded());
		bool success = lu_of_A.solve(aAndBVars.GetBVarsConst(),&m_u);
		wxASSERT(success);
	}
Beispiel #22
0
void testEigen(int m, int n, int nnz, std::vector<int>& rows, std::vector<int>& cols,
		std::vector<double>& values, double* matB){

	double start, stop, time_to_solve, time_to_build;
    double tol=1e-9;
    Eigen::SparseMatrix<double> A;

    std::vector< Eigen::Triplet<double> > trips;
    trips.reserve(m * n);

    for (int k = 0; k < nnz; k++){
    	double _val = values[k];
    	int i = rows[k];
    	int j = cols[k];

    	if (fabs(_val) > tol){
    		trips.push_back(Eigen::Triplet<double>(i-1,j-1,_val));
        }
    }



    //NOTE: setFromTriples() accumulates contributions to the same (i,j)!
    A.resize(m, n);
    start = second();
    A.setFromTriplets(trips.begin(), trips.end());
    stop = second();
    time_to_build = stop - start;

	Eigen::SparseLU< Eigen::SparseMatrix<double>, Eigen::COLAMDOrdering<int> > solverLU;



    Eigen::VectorXd b; b.resize(m);
    for (int i = 0; i < m; i++ ) b(i) = matB[i];

	printf("\nProcessing in Eigen using LU...\n");
	start = second();
	solverLU.compute(A);
	Eigen::VectorXd X = solverLU.solve(b);
	stop = second();
	time_to_solve = stop - start;

    Eigen::VectorXd ax = A * X;
    Eigen::VectorXd bMinusAx = b - ax;

	double h_r[m];
    for (int i=0; i<m; i++) h_r[i]=bMinusAx(i);

    double r_inf = vec_norminf(m, h_r);

    printf("(Eigen) |b - A*x| = %E \n", r_inf);
    printf("(Eigen) Time to build(sec): %f\n", time_to_build);
    printf("(Eigen) Time (sec): %f\n", time_to_solve);
}
Beispiel #23
0
IGL_INLINE void igl::components(
  const Eigen::SparseMatrix<AScalar> & A,
  Eigen::PlainObjectBase<DerivedC> & C,
  Eigen::PlainObjectBase<Derivedcounts> & counts)
{
  using namespace Eigen;
  using namespace std;
  assert(A.rows() == A.cols() && "A should be square.");
  const size_t n = A.rows();
  Array<bool,Dynamic,1> seen = Array<bool,Dynamic,1>::Zero(n,1);
  C.resize(n,1);
  typename DerivedC::Scalar id = 0;
  vector<typename Derivedcounts::Scalar> vcounts;
  // breadth first search
  for(int k=0; k<A.outerSize(); ++k)
  {
    if(seen(k))
    {
      continue;
    }
    queue<int> Q;
    Q.push(k);
    vcounts.push_back(0);
    while(!Q.empty())
    {
      const int f = Q.front();
      Q.pop();
      if(seen(f))
      {
        continue;
      }
      seen(f) = true;
      C(f,0) = id;
      vcounts[id]++;
      // Iterate over inside
      for(typename SparseMatrix<AScalar>::InnerIterator it (A,f); it; ++it)
      {
        const int g = it.index();
        if(!seen(g) && it.value())
        {
          Q.push(g);
        }
      }
    }
    id++;
  }
  assert((size_t) id == vcounts.size());
  const size_t ncc = vcounts.size();
  assert((size_t)C.maxCoeff()+1 == ncc);
  counts.resize(ncc,1);
  for(size_t i = 0;i<ncc;i++)
  {
    counts(i) = vcounts[i];
  }
}
inline
void
space_operator(
    Eigen::SparseMatrix<double>& result,
    Eigen::SparseMatrix<double>& laplace,
    const double multiplier,
    Eigen::SparseMatrix<double>& unit_matrix)
{
  result.resize(unit_matrix.rows(), unit_matrix.cols());
  result = laplace*multiplier+unit_matrix;
}
Beispiel #25
0
void MacauOnePrior<FType>::sample_latents(
    Eigen::MatrixXd &U,
    const Eigen::SparseMatrix<double> &Ymat,
    double mean_value,
    const Eigen::MatrixXd &V,
    double alpha,
    const int num_latent)
{
  const int N = U.cols();
  const int D = U.rows();

#pragma omp parallel for schedule(dynamic, 4)
  for (int i = 0; i < N; i++) {

    const int nnz = Ymat.outerIndexPtr()[i + 1] - Ymat.outerIndexPtr()[i];
    VectorXd Yhat(nnz);

    // precalculating Yhat and Qi
    int idx = 0;
    VectorXd Qi = lambda;
    for (SparseMatrix<double>::InnerIterator it(Ymat, i); it; ++it, idx++) {
      Qi.noalias() += alpha * V.col(it.row()).cwiseAbs2();
      Yhat(idx)     = mean_value + U.col(i).dot( V.col(it.row()) );
    }
    VectorXd rnorms(num_latent);
    bmrandn_single(rnorms);

    for (int d = 0; d < D; d++) {
      // computing Lid
      const double uid = U(d, i);
      double Lid = lambda(d) * (mu(d) + Uhat(d, i));

      idx = 0;
      for ( SparseMatrix<double>::InnerIterator it(Ymat, i); it; ++it, idx++) {
        const double vjd = V(d, it.row());
        // L_id += alpha * (Y_ij - k_ijd) * v_jd
        Lid += alpha * (it.value() - (Yhat(idx) - uid*vjd)) * vjd;
      }
      // Now use Lid and Qid to update uid
      double uid_old = U(d, i);
      double uid_var = 1.0 / Qi(d);

      // sampling new u_id ~ Norm(Lid / Qid, 1/Qid)
      U(d, i) = Lid * uid_var + sqrt(uid_var) * rnorms(d);

      // updating Yhat
      double uid_delta = U(d, i) - uid_old;
      idx = 0;
      for (SparseMatrix<double>::InnerIterator it(Ymat, i); it; ++it, idx++) {
        Yhat(idx) += uid_delta * V(d, it.row());
      }
    }
  }
}
Beispiel #26
0
IGL_INLINE void igl::speye(const int m, const int n, Eigen::SparseMatrix<T> & I)
{
  // size of diagonal
  int d = (m<n?m:n);
  I = Eigen::SparseMatrix<T>(m,n);
  I.reserve(d);
  for(int i = 0;i<d;i++)
  {
    I.insert(i,i) = 1.0;
  }
  I.finalize();
}
Beispiel #27
0
// Test that column indexes of values from sparse matrix in sparse
// format are extracted after makeCompressed().
TEST(SparseStuff, csr_extract_v_sparse_compressed) {
  stan::math::matrix_d m(2, 3);
  Eigen::SparseMatrix<double, Eigen::RowMajor> a;
  m << 2.0, 4.0, 6.0, 0.0, 0.0, 0.0;
  a = m.sparseView();
  a.makeCompressed();
  std::vector<int> result = stan::math::csr_extract_v(a);
  EXPECT_EQ(1, result[0]);
  EXPECT_EQ(2, result[1]);
  EXPECT_EQ(3, result[2]);
  EXPECT_EQ(3, result.size());
}
Beispiel #28
0
void createSearchKey(unsigned int numberRows, unsigned int NBFS, std::vector<int> &search_key, const Eigen::SparseMatrix<int> &EdgeMatrix)
{

//columndegree contains number of nonzeros per column
//for removing searchkey values that are not connected to main graph
    std::vector<int> columndegree;
    columndegree.reserve(numberRows);

    for (unsigned int i = 0; i < numberRows; i++)
    {
        columndegree.push_back(EdgeMatrix.outerIndexPtr()[i+1]-EdgeMatrix.outerIndexPtr()[i]);
    }

//generate search key values based on time seed
    std::mt19937 generator(std::chrono::system_clock::now().time_since_epoch()/std::chrono::seconds(1));

    std::cout << "creating search key vector" << std::endl;
    for (unsigned int i = 0; i < numberRows; i++)
    {
        search_key.push_back(i);
    }
//shuffle search key values
    std::shuffle(search_key.begin(),search_key.end(),generator);

//take first 64 or entire search key, whichever is smaller
    if (search_key.size() > NBFS)
    {
        for (unsigned int i = 0; i < NBFS+20; i++)
        {
            //remove search key values that aren't connected to main graph
            if (columndegree.at(search_key.at(i)) == 0)
            {
                search_key.erase(search_key.begin()+i);
                i--;
            }
        }
        search_key.erase(search_key.begin()+NBFS, search_key.end());
    }

    std::cout << "Removing search keys with no edges" << std::endl;
    for (unsigned int i = 0; i < search_key.size(); i++)
    {
        //remove search key values that aren't connected to main graph
        if (columndegree.at(search_key.at(i)) == 0)
        {
            search_key.erase(search_key.begin()+i);
            i--;
        }
    }

    search_key.shrink_to_fit();
}
std::vector<double> getRowSum(const Eigen::SparseMatrix<int,Eigen::RowMajor>& adjacencyMatrix)
{
  int rowSize = adjacencyMatrix.rows();
  std::vector<double> rowSum;
  rowSum.reserve(rowSize);
  for(int i=0; i<rowSize;++i){
     double value = adjacencyMatrix.innerVector(i).sum();
     rowSum.push_back(value);
  }

  return rowSum;

}
Beispiel #30
0
IGL_INLINE bool igl::GeneralPolyVectorFieldFinder<DerivedV, DerivedF>::
                     solve(const Eigen::VectorXi &isConstrained,
                           const Eigen::Matrix<typename DerivedV::Scalar, Eigen::Dynamic, Eigen::Dynamic> &cfW,
                           const Eigen::VectorXi &rootsIndex,
                           Eigen::Matrix<typename DerivedV::Scalar, Eigen::Dynamic, Eigen::Dynamic> &output)
{

  // polynomial is of the form:
  // z^(2n) +
  // -c[0]z^(2n-1) +
  // c[1]z^(2n-2) +
  // -c[2]z^(2n-3) +
  // ... +
  // (-1)^n c[n-1]

  std::vector<Eigen::Matrix<std::complex<typename DerivedV::Scalar>, Eigen::Dynamic,1>> coeffs(n,Eigen::Matrix<std::complex<typename DerivedV::Scalar>, Eigen::Dynamic,1>::Zero(numF, 1));

  for (int i =0; i<n; ++i)
  {
    int degree = i+1;

    Eigen::Matrix<std::complex<typename DerivedV::Scalar>, Eigen::Dynamic,1> Ck;
    getGeneralCoeffConstraints(isConstrained,
                               cfW,
                               i,
                               rootsIndex,
                               Ck);

    Eigen::SparseMatrix<std::complex<typename DerivedV::Scalar> > DD;
    computeCoefficientLaplacian(degree, DD);
    Eigen::SparseMatrix<std::complex<typename DerivedV::Scalar> > f; f.resize(numF,1);

    if (isConstrained.sum() == numF)
      coeffs[i] = Ck;
    else
      minQuadWithKnownMini(DD, f, isConstrained, Ck, coeffs[i]);
  }

  std::vector<Eigen::Matrix<typename DerivedV::Scalar, Eigen::Dynamic, 2> > pv;
  setFieldFromGeneralCoefficients(coeffs, pv);

  output.setZero(numF,3*n);
  for (int fi=0; fi<numF; ++fi)
  {
    const Eigen::Matrix<typename DerivedV::Scalar, 1, 3> &b1 = B1.row(fi);
    const Eigen::Matrix<typename DerivedV::Scalar, 1, 3> &b2 = B2.row(fi);
    for (int i=0; i<n; ++i)
      output.block(fi,3*i, 1, 3) = pv[i](fi,0)*b1 + pv[i](fi,1)*b2;
  }
  return true;
}