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339 lines
18 KiB
Plaintext
339 lines
18 KiB
Plaintext
namespace Eigen {
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/** \eigenManualPage TutorialSparse Sparse matrix manipulations
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\eigenAutoToc
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Manipulating and solving sparse problems involves various modules which are summarized below:
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<table class="manual">
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<tr><th>Module</th><th>Header file</th><th>Contents</th></tr>
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<tr><td>\link SparseCore_Module SparseCore \endlink</td><td>\code#include <Eigen/SparseCore>\endcode</td><td>SparseMatrix and SparseVector classes, matrix assembly, basic sparse linear algebra (including sparse triangular solvers)</td></tr>
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<tr><td>\link SparseCholesky_Module SparseCholesky \endlink</td><td>\code#include <Eigen/SparseCholesky>\endcode</td><td>Direct sparse LLT and LDLT Cholesky factorization to solve sparse self-adjoint positive definite problems</td></tr>
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<tr><td>\link SparseLU_Module SparseLU \endlink</td><td>\code #include<Eigen/SparseLU> \endcode</td>
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<td>%Sparse LU factorization to solve general square sparse systems</td></tr>
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<tr><td>\link SparseQR_Module SparseQR \endlink</td><td>\code #include<Eigen/SparseQR>\endcode </td><td>%Sparse QR factorization for solving sparse linear least-squares problems</td></tr>
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<tr><td>\link IterativeLinearSolvers_Module IterativeLinearSolvers \endlink</td><td>\code#include <Eigen/IterativeLinearSolvers>\endcode</td><td>Iterative solvers to solve large general linear square problems (including self-adjoint positive definite problems)</td></tr>
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<tr><td>\link Sparse_Module Sparse \endlink</td><td>\code#include <Eigen/Sparse>\endcode</td><td>Includes all the above modules</td></tr>
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</table>
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\section TutorialSparseIntro Sparse matrix format
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In many applications (e.g., finite element methods) it is common to deal with very large matrices where only a few coefficients are different from zero. In such cases, memory consumption can be reduced and performance increased by using a specialized representation storing only the nonzero coefficients. Such a matrix is called a sparse matrix.
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\b The \b %SparseMatrix \b class
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The class SparseMatrix is the main sparse matrix representation of Eigen's sparse module; it offers high performance and low memory usage.
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It implements a more versatile variant of the widely-used Compressed Column (or Row) Storage scheme.
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It consists of four compact arrays:
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- \c Values: stores the coefficient values of the non-zeros.
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- \c InnerIndices: stores the row (resp. column) indices of the non-zeros.
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- \c OuterStarts: stores for each column (resp. row) the index of the first non-zero in the previous two arrays.
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- \c InnerNNZs: stores the number of non-zeros of each column (resp. row).
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The word \c inner refers to an \em inner \em vector that is a column for a column-major matrix, or a row for a row-major matrix.
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The word \c outer refers to the other direction.
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This storage scheme is better explained on an example. The following matrix
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<table class="manual">
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<tr><td> 0</td><td>3</td><td> 0</td><td>0</td><td> 0</td></tr>
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<tr><td>22</td><td>0</td><td> 0</td><td>0</td><td>17</td></tr>
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<tr><td> 7</td><td>5</td><td> 0</td><td>1</td><td> 0</td></tr>
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<tr><td> 0</td><td>0</td><td> 0</td><td>0</td><td> 0</td></tr>
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<tr><td> 0</td><td>0</td><td>14</td><td>0</td><td> 8</td></tr>
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</table>
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and one of its possible sparse, \b column \b major representation:
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<table class="manual">
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<tr><td>Values:</td> <td>22</td><td>7</td><td>_</td><td>3</td><td>5</td><td>14</td><td>_</td><td>_</td><td>1</td><td>_</td><td>17</td><td>8</td></tr>
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<tr><td>InnerIndices:</td> <td> 1</td><td>2</td><td>_</td><td>0</td><td>2</td><td> 4</td><td>_</td><td>_</td><td>2</td><td>_</td><td> 1</td><td>4</td></tr>
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</table>
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<table class="manual">
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<tr><td>OuterStarts:</td><td>0</td><td>3</td><td>5</td><td>8</td><td>10</td><td>\em 12 </td></tr>
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<tr><td>InnerNNZs:</td> <td>2</td><td>2</td><td>1</td><td>1</td><td> 2</td><td></td></tr>
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</table>
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Currently the elements of a given inner vector are guaranteed to be always sorted by increasing inner indices.
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The \c "_" indicates available free space to quickly insert new elements.
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Assuming no reallocation is needed, the insertion of a random element is therefore in O(nnz_j) where nnz_j is the number of nonzeros of the respective inner vector.
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On the other hand, inserting elements with increasing inner indices in a given inner vector is much more efficient since this only requires to increase the respective \c InnerNNZs entry that is a O(1) operation.
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The case where no empty space is available is a special case, and is refered as the \em compressed mode.
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It corresponds to the widely used Compressed Column (or Row) Storage schemes (CCS or CRS).
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Any SparseMatrix can be turned to this form by calling the SparseMatrix::makeCompressed() function.
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In this case, one can remark that the \c InnerNNZs array is redundant with \c OuterStarts because we the equality: \c InnerNNZs[j] = \c OuterStarts[j+1]-\c OuterStarts[j].
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Therefore, in practice a call to SparseMatrix::makeCompressed() frees this buffer.
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It is worth noting that most of our wrappers to external libraries requires compressed matrices as inputs.
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The results of %Eigen's operations always produces \b compressed sparse matrices.
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On the other hand, the insertion of a new element into a SparseMatrix converts this later to the \b uncompressed mode.
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Here is the previous matrix represented in compressed mode:
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<table class="manual">
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<tr><td>Values:</td> <td>22</td><td>7</td><td>3</td><td>5</td><td>14</td><td>1</td><td>17</td><td>8</td></tr>
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<tr><td>InnerIndices:</td> <td> 1</td><td>2</td><td>0</td><td>2</td><td> 4</td><td>2</td><td> 1</td><td>4</td></tr>
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</table>
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<table class="manual">
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<tr><td>OuterStarts:</td><td>0</td><td>2</td><td>4</td><td>5</td><td>6</td><td>\em 8 </td></tr>
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</table>
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A SparseVector is a special case of a SparseMatrix where only the \c Values and \c InnerIndices arrays are stored.
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There is no notion of compressed/uncompressed mode for a SparseVector.
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\section TutorialSparseExample First example
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Before describing each individual class, let's start with the following typical example: solving the Laplace equation \f$ \nabla u = 0 \f$ on a regular 2D grid using a finite difference scheme and Dirichlet boundary conditions.
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Such problem can be mathematically expressed as a linear problem of the form \f$ Ax=b \f$ where \f$ x \f$ is the vector of \c m unknowns (in our case, the values of the pixels), \f$ b \f$ is the right hand side vector resulting from the boundary conditions, and \f$ A \f$ is an \f$ m \times m \f$ matrix containing only a few non-zero elements resulting from the discretization of the Laplacian operator.
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<table class="manual">
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<tr><td>
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\include Tutorial_sparse_example.cpp
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</td>
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<td>
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\image html Tutorial_sparse_example.jpeg
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</td></tr></table>
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In this example, we start by defining a column-major sparse matrix type of double \c SparseMatrix<double>, and a triplet list of the same scalar type \c Triplet<double>. A triplet is a simple object representing a non-zero entry as the triplet: \c row index, \c column index, \c value.
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In the main function, we declare a list \c coefficients of triplets (as a std vector) and the right hand side vector \f$ b \f$ which are filled by the \a buildProblem function.
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The raw and flat list of non-zero entries is then converted to a true SparseMatrix object \c A.
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Note that the elements of the list do not have to be sorted, and possible duplicate entries will be summed up.
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The last step consists of effectively solving the assembled problem.
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Since the resulting matrix \c A is symmetric by construction, we can perform a direct Cholesky factorization via the SimplicialLDLT class which behaves like its LDLT counterpart for dense objects.
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The resulting vector \c x contains the pixel values as a 1D array which is saved to a jpeg file shown on the right of the code above.
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Describing the \a buildProblem and \a save functions is out of the scope of this tutorial. They are given \ref TutorialSparse_example_details "here" for the curious and reproducibility purpose.
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\section TutorialSparseSparseMatrix The SparseMatrix class
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\b %Matrix \b and \b vector \b properties \n
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The SparseMatrix and SparseVector classes take three template arguments:
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* the scalar type (e.g., double)
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* the storage order (ColMajor or RowMajor, the default is ColMajor)
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* the inner index type (default is \c int).
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As for dense Matrix objects, constructors takes the size of the object.
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Here are some examples:
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\code
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SparseMatrix<std::complex<float> > mat(1000,2000); // declares a 1000x2000 column-major compressed sparse matrix of complex<float>
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SparseMatrix<double,RowMajor> mat(1000,2000); // declares a 1000x2000 row-major compressed sparse matrix of double
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SparseVector<std::complex<float> > vec(1000); // declares a column sparse vector of complex<float> of size 1000
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SparseVector<double,RowMajor> vec(1000); // declares a row sparse vector of double of size 1000
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\endcode
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In the rest of the tutorial, \c mat and \c vec represent any sparse-matrix and sparse-vector objects, respectively.
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The dimensions of a matrix can be queried using the following functions:
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<table class="manual">
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<tr><td>Standard \n dimensions</td><td>\code
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mat.rows()
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mat.cols()\endcode</td>
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<td>\code
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vec.size() \endcode</td>
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</tr>
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<tr><td>Sizes along the \n inner/outer dimensions</td><td>\code
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mat.innerSize()
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mat.outerSize()\endcode</td>
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<td></td>
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</tr>
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<tr><td>Number of non \n zero coefficients</td><td>\code
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mat.nonZeros() \endcode</td>
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<td>\code
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vec.nonZeros() \endcode</td></tr>
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</table>
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\b Iterating \b over \b the \b nonzero \b coefficients \n
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Random access to the elements of a sparse object can be done through the \c coeffRef(i,j) function.
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However, this function involves a quite expensive binary search.
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In most cases, one only wants to iterate over the non-zeros elements. This is achieved by a standard loop over the outer dimension, and then by iterating over the non-zeros of the current inner vector via an InnerIterator. Thus, the non-zero entries have to be visited in the same order than the storage order.
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Here is an example:
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<table class="manual">
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<tr><td>
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\code
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SparseMatrix<double> mat(rows,cols);
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for (int k=0; k<mat.outerSize(); ++k)
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for (SparseMatrix<double>::InnerIterator it(mat,k); it; ++it)
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{
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it.value();
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it.row(); // row index
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it.col(); // col index (here it is equal to k)
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it.index(); // inner index, here it is equal to it.row()
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}
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\endcode
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</td><td>
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\code
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SparseVector<double> vec(size);
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for (SparseVector<double>::InnerIterator it(vec); it; ++it)
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{
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it.value(); // == vec[ it.index() ]
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it.index();
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}
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\endcode
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</td></tr>
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</table>
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For a writable expression, the referenced value can be modified using the valueRef() function.
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If the type of the sparse matrix or vector depends on a template parameter, then the \c typename keyword is
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required to indicate that \c InnerIterator denotes a type; see \ref TopicTemplateKeyword for details.
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\section TutorialSparseFilling Filling a sparse matrix
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Because of the special storage scheme of a SparseMatrix, special care has to be taken when adding new nonzero entries.
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For instance, the cost of a single purely random insertion into a SparseMatrix is \c O(nnz), where \c nnz is the current number of non-zero coefficients.
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The simplest way to create a sparse matrix while guaranteeing good performance is thus to first build a list of so-called \em triplets, and then convert it to a SparseMatrix.
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Here is a typical usage example:
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\code
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typedef Eigen::Triplet<double> T;
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std::vector<T> tripletList;
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tripletList.reserve(estimation_of_entries);
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for(...)
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{
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// ...
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tripletList.push_back(T(i,j,v_ij));
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}
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SparseMatrixType mat(rows,cols);
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mat.setFromTriplets(tripletList.begin(), tripletList.end());
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// mat is ready to go!
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\endcode
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The \c std::vector of triplets might contain the elements in arbitrary order, and might even contain duplicated elements that will be summed up by setFromTriplets().
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See the SparseMatrix::setFromTriplets() function and class Triplet for more details.
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In some cases, however, slightly higher performance, and lower memory consumption can be reached by directly inserting the non-zeros into the destination matrix.
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A typical scenario of this approach is illustrated bellow:
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\code
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1: SparseMatrix<double> mat(rows,cols); // default is column major
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2: mat.reserve(VectorXi::Constant(cols,6));
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3: for each i,j such that v_ij != 0
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4: mat.insert(i,j) = v_ij; // alternative: mat.coeffRef(i,j) += v_ij;
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5: mat.makeCompressed(); // optional
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\endcode
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- The key ingredient here is the line 2 where we reserve room for 6 non-zeros per column. In many cases, the number of non-zeros per column or row can easily be known in advance. If it varies significantly for each inner vector, then it is possible to specify a reserve size for each inner vector by providing a vector object with an operator[](int j) returning the reserve size of the \c j-th inner vector (e.g., via a VectorXi or std::vector<int>). If only a rought estimate of the number of nonzeros per inner-vector can be obtained, it is highly recommended to overestimate it rather than the opposite. If this line is omitted, then the first insertion of a new element will reserve room for 2 elements per inner vector.
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- The line 4 performs a sorted insertion. In this example, the ideal case is when the \c j-th column is not full and contains non-zeros whose inner-indices are smaller than \c i. In this case, this operation boils down to trivial O(1) operation.
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- When calling insert(i,j) the element \c i \c ,j must not already exists, otherwise use the coeffRef(i,j) method that will allow to, e.g., accumulate values. This method first performs a binary search and finally calls insert(i,j) if the element does not already exist. It is more flexible than insert() but also more costly.
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- The line 5 suppresses the remaining empty space and transforms the matrix into a compressed column storage.
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\section TutorialSparseFeatureSet Supported operators and functions
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Because of their special storage format, sparse matrices cannot offer the same level of flexibility than dense matrices.
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In Eigen's sparse module we chose to expose only the subset of the dense matrix API which can be efficiently implemented.
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In the following \em sm denotes a sparse matrix, \em sv a sparse vector, \em dm a dense matrix, and \em dv a dense vector.
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\subsection TutorialSparse_BasicOps Basic operations
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%Sparse expressions support most of the unary and binary coefficient wise operations:
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\code
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sm1.real() sm1.imag() -sm1 0.5*sm1
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sm1+sm2 sm1-sm2 sm1.cwiseProduct(sm2)
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\endcode
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However, a strong restriction is that the storage orders must match. For instance, in the following example:
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\code
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sm4 = sm1 + sm2 + sm3;
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\endcode
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sm1, sm2, and sm3 must all be row-major or all column major.
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On the other hand, there is no restriction on the target matrix sm4.
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For instance, this means that for computing \f$ A^T + A \f$, the matrix \f$ A^T \f$ must be evaluated into a temporary matrix of compatible storage order:
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\code
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SparseMatrix<double> A, B;
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B = SparseMatrix<double>(A.transpose()) + A;
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\endcode
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Binary coefficient wise operators can also mix sparse and dense expressions:
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\code
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sm2 = sm1.cwiseProduct(dm1);
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dm2 = sm1 + dm1;
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\endcode
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%Sparse expressions also support transposition:
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\code
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sm1 = sm2.transpose();
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sm1 = sm2.adjoint();
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\endcode
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However, there is no transposeInPlace() method.
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\subsection TutorialSparse_Products Matrix products
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%Eigen supports various kind of sparse matrix products which are summarize below:
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- \b sparse-dense:
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\code
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dv2 = sm1 * dv1;
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dm2 = dm1 * sm1.adjoint();
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dm2 = 2. * sm1 * dm1;
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\endcode
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- \b symmetric \b sparse-dense. The product of a sparse symmetric matrix with a dense matrix (or vector) can also be optimized by specifying the symmetry with selfadjointView():
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\code
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dm2 = sm1.selfadjointView<>() * dm1; // if all coefficients of A are stored
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dm2 = A.selfadjointView<Upper>() * dm1; // if only the upper part of A is stored
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dm2 = A.selfadjointView<Lower>() * dm1; // if only the lower part of A is stored
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\endcode
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- \b sparse-sparse. For sparse-sparse products, two different algorithms are available. The default one is conservative and preserve the explicit zeros that might appear:
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\code
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sm3 = sm1 * sm2;
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sm3 = 4 * sm1.adjoint() * sm2;
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\endcode
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The second algorithm prunes on the fly the explicit zeros, or the values smaller than a given threshold. It is enabled and controlled through the prune() functions:
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\code
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sm3 = (sm1 * sm2).pruned(); // removes numerical zeros
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sm3 = (sm1 * sm2).pruned(ref); // removes elements much smaller than ref
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sm3 = (sm1 * sm2).pruned(ref,epsilon); // removes elements smaller than ref*epsilon
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\endcode
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- \b permutations. Finally, permutations can be applied to sparse matrices too:
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\code
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PermutationMatrix<Dynamic,Dynamic> P = ...;
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sm2 = P * sm1;
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sm2 = sm1 * P.inverse();
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sm2 = sm1.transpose() * P;
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\endcode
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\subsection TutorialSparse_TriangularSelfadjoint Triangular and selfadjoint views
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Just as with dense matrices, the triangularView() function can be used to address a triangular part of the matrix, and perform triangular solves with a dense right hand side:
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\code
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dm2 = sm1.triangularView<Lower>(dm1);
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dv2 = sm1.transpose().triangularView<Upper>(dv1);
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\endcode
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The selfadjointView() function permits various operations:
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- optimized sparse-dense matrix products:
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\code
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dm2 = sm1.selfadjointView<>() * dm1; // if all coefficients of A are stored
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dm2 = A.selfadjointView<Upper>() * dm1; // if only the upper part of A is stored
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dm2 = A.selfadjointView<Lower>() * dm1; // if only the lower part of A is stored
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\endcode
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- copy of triangular parts:
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\code
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sm2 = sm1.selfadjointView<Upper>(); // makes a full selfadjoint matrix from the upper triangular part
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sm2.selfadjointView<Lower>() = sm1.selfadjointView<Upper>(); // copies the upper triangular part to the lower triangular part
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\endcode
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- application of symmetric permutations:
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\code
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PermutationMatrix<Dynamic,Dynamic> P = ...;
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sm2 = A.selfadjointView<Upper>().twistedBy(P); // compute P S P' from the upper triangular part of A, and make it a full matrix
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sm2.selfadjointView<Lower>() = A.selfadjointView<Lower>().twistedBy(P); // compute P S P' from the lower triangular part of A, and then only compute the lower part
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\endcode
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Please, refer to the \link SparseQuickRefPage Quick Reference \endlink guide for the list of supported operations. The list of linear solvers available is \link TopicSparseSystems here. \endlink
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*/
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}
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