11 #ifndef EIGEN_REAL_SCHUR_H 12 #define EIGEN_REAL_SCHUR_H 14 #include "./HessenbergDecomposition.h" 57 typedef _MatrixType MatrixType;
59 RowsAtCompileTime = MatrixType::RowsAtCompileTime,
60 ColsAtCompileTime = MatrixType::ColsAtCompileTime,
61 Options = MatrixType::Options,
62 MaxRowsAtCompileTime = MatrixType::MaxRowsAtCompileTime,
63 MaxColsAtCompileTime = MatrixType::MaxColsAtCompileTime
65 typedef typename MatrixType::Scalar Scalar;
66 typedef std::complex<typename NumTraits<Scalar>::Real> ComplexScalar;
86 m_workspaceVector(size),
88 m_isInitialized(false),
89 m_matUisUptodate(false),
103 template<
typename InputType>
105 : m_matT(matrix.rows(),matrix.cols()),
106 m_matU(matrix.rows(),matrix.cols()),
107 m_workspaceVector(matrix.rows()),
108 m_hess(matrix.rows()),
109 m_isInitialized(false),
110 m_matUisUptodate(false),
129 eigen_assert(m_isInitialized &&
"RealSchur is not initialized.");
130 eigen_assert(m_matUisUptodate &&
"The matrix U has not been computed during the RealSchur decomposition.");
146 eigen_assert(m_isInitialized &&
"RealSchur is not initialized.");
169 template<
typename InputType>
189 template<
typename HessMatrixType,
typename OrthMatrixType>
197 eigen_assert(m_isInitialized &&
"RealSchur is not initialized.");
208 m_maxIters = maxIters;
229 ColumnVectorType m_workspaceVector;
232 bool m_isInitialized;
233 bool m_matUisUptodate;
238 Scalar computeNormOfT();
239 Index findSmallSubdiagEntry(Index iu);
240 void splitOffTwoRows(Index iu,
bool computeU,
const Scalar& exshift);
241 void computeShift(Index iu, Index iter, Scalar& exshift, Vector3s& shiftInfo);
242 void initFrancisQRStep(Index il, Index iu,
const Vector3s& shiftInfo, Index& im, Vector3s& firstHouseholderVector);
243 void performFrancisQRStep(Index il, Index im, Index iu,
bool computeU,
const Vector3s& firstHouseholderVector, Scalar* workspace);
247 template<
typename MatrixType>
248 template<
typename InputType>
251 const Scalar considerAsZero = (std::numeric_limits<Scalar>::min)();
253 eigen_assert(matrix.
cols() == matrix.
rows());
254 Index maxIters = m_maxIters;
258 Scalar scale = matrix.
derived().cwiseAbs().maxCoeff();
259 if(scale<considerAsZero)
261 m_matT.setZero(matrix.
rows(),matrix.
cols());
263 m_matU.setIdentity(matrix.
rows(),matrix.
cols());
265 m_isInitialized =
true;
266 m_matUisUptodate = computeU;
280 template<
typename MatrixType>
281 template<
typename HessMatrixType,
typename OrthMatrixType>
290 Index maxIters = m_maxIters;
293 m_workspaceVector.
resize(m_matT.cols());
294 Scalar* workspace = &m_workspaceVector.
coeffRef(0);
300 Index iu = m_matT.cols() - 1;
304 Scalar norm = computeNormOfT();
310 Index il = findSmallSubdiagEntry(iu);
315 m_matT.coeffRef(iu,iu) = m_matT.coeff(iu,iu) + exshift;
317 m_matT.coeffRef(iu, iu-1) = Scalar(0);
323 splitOffTwoRows(iu, computeU, exshift);
330 Vector3s firstHouseholderVector(0,0,0), shiftInfo;
331 computeShift(iu, iter, exshift, shiftInfo);
333 totalIter = totalIter + 1;
334 if (totalIter > maxIters)
break;
336 initFrancisQRStep(il, iu, shiftInfo, im, firstHouseholderVector);
337 performFrancisQRStep(il, im, iu, computeU, firstHouseholderVector, workspace);
341 if(totalIter <= maxIters)
346 m_isInitialized =
true;
347 m_matUisUptodate = computeU;
352 template<
typename MatrixType>
355 const Index size = m_matT.cols();
360 for (
Index j = 0; j < size; ++j)
361 norm += m_matT.col(j).segment(0, (std::min)(size,j+2)).cwiseAbs().sum();
366 template<
typename MatrixType>
373 Scalar s =
abs(m_matT.coeff(res-1,res-1)) +
abs(m_matT.coeff(res,res));
382 template<
typename MatrixType>
387 const Index size = m_matT.cols();
391 Scalar p = Scalar(0.5) * (m_matT.coeff(iu-1,iu-1) - m_matT.coeff(iu,iu));
392 Scalar q = p * p + m_matT.coeff(iu,iu-1) * m_matT.coeff(iu-1,iu);
393 m_matT.coeffRef(iu,iu) += exshift;
394 m_matT.coeffRef(iu-1,iu-1) += exshift;
401 rot.
makeGivens(p + z, m_matT.coeff(iu, iu-1));
403 rot.
makeGivens(p - z, m_matT.coeff(iu, iu-1));
405 m_matT.rightCols(size-iu+1).applyOnTheLeft(iu-1, iu, rot.
adjoint());
406 m_matT.topRows(iu+1).applyOnTheRight(iu-1, iu, rot);
407 m_matT.coeffRef(iu, iu-1) = Scalar(0);
409 m_matU.applyOnTheRight(iu-1, iu, rot);
413 m_matT.coeffRef(iu-1, iu-2) = Scalar(0);
417 template<
typename MatrixType>
422 shiftInfo.
coeffRef(0) = m_matT.coeff(iu,iu);
423 shiftInfo.
coeffRef(1) = m_matT.coeff(iu-1,iu-1);
424 shiftInfo.
coeffRef(2) = m_matT.coeff(iu,iu-1) * m_matT.coeff(iu-1,iu);
429 exshift += shiftInfo.
coeff(0);
430 for (
Index i = 0; i <= iu; ++i)
431 m_matT.coeffRef(i,i) -= shiftInfo.
coeff(0);
432 Scalar s =
abs(m_matT.coeff(iu,iu-1)) +
abs(m_matT.coeff(iu-1,iu-2));
433 shiftInfo.
coeffRef(0) = Scalar(0.75) * s;
434 shiftInfo.
coeffRef(1) = Scalar(0.75) * s;
435 shiftInfo.
coeffRef(2) = Scalar(-0.4375) * s * s;
441 Scalar s = (shiftInfo.
coeff(1) - shiftInfo.
coeff(0)) / Scalar(2.0);
442 s = s * s + shiftInfo.
coeff(2);
448 s = s + (shiftInfo.
coeff(1) - shiftInfo.
coeff(0)) / Scalar(2.0);
449 s = shiftInfo.
coeff(0) - shiftInfo.
coeff(2) / s;
451 for (
Index i = 0; i <= iu; ++i)
452 m_matT.coeffRef(i,i) -= s;
459 template<
typename MatrixType>
463 Vector3s& v = firstHouseholderVector;
465 for (im = iu-2; im >= il; --im)
467 const Scalar Tmm = m_matT.coeff(im,im);
468 const Scalar r = shiftInfo.
coeff(0) - Tmm;
469 const Scalar s = shiftInfo.
coeff(1) - Tmm;
470 v.
coeffRef(0) = (r * s - shiftInfo.
coeff(2)) / m_matT.coeff(im+1,im) + m_matT.coeff(im,im+1);
471 v.
coeffRef(1) = m_matT.coeff(im+1,im+1) - Tmm - r - s;
472 v.
coeffRef(2) = m_matT.coeff(im+2,im+1);
476 const Scalar lhs = m_matT.coeff(im,im-1) * (
abs(v.
coeff(1)) +
abs(v.
coeff(2)));
477 const Scalar rhs = v.
coeff(0) * (
abs(m_matT.coeff(im-1,im-1)) +
abs(Tmm) +
abs(m_matT.coeff(im+1,im+1)));
484 template<
typename MatrixType>
487 eigen_assert(im >= il);
488 eigen_assert(im <= iu-2);
490 const Index size = m_matT.cols();
492 for (
Index k = im; k <= iu-2; ++k)
494 bool firstIteration = (k == im);
498 v = firstHouseholderVector;
500 v = m_matT.template block<3,1>(k,k-1);
504 v.makeHouseholder(ess, tau, beta);
506 if (beta != Scalar(0))
508 if (firstIteration && k > il)
509 m_matT.coeffRef(k,k-1) = -m_matT.coeff(k,k-1);
510 else if (!firstIteration)
511 m_matT.coeffRef(k,k-1) = beta;
514 m_matT.block(k, k, 3, size-k).applyHouseholderOnTheLeft(ess, tau, workspace);
515 m_matT.block(0, k, (std::min)(iu,k+3) + 1, 3).applyHouseholderOnTheRight(ess, tau, workspace);
517 m_matU.block(0, k, size, 3).applyHouseholderOnTheRight(ess, tau, workspace);
526 if (beta != Scalar(0))
528 m_matT.coeffRef(iu-1, iu-2) = beta;
529 m_matT.block(iu-1, iu-1, 2, size-iu+1).applyHouseholderOnTheLeft(ess, tau, workspace);
530 m_matT.block(0, iu-1, iu+1, 2).applyHouseholderOnTheRight(ess, tau, workspace);
532 m_matU.block(0, iu-1, size, 2).applyHouseholderOnTheRight(ess, tau, workspace);
536 for (
Index i = im+2; i <= iu; ++i)
538 m_matT.coeffRef(i,i-2) = Scalar(0);
540 m_matT.coeffRef(i,i-3) = Scalar(0);
546 #endif // EIGEN_REAL_SCHUR_H void makeHouseholder(EssentialPart &essential, Scalar &tau, RealScalar &beta) const
Definition: Householder.h:65
Performs a real Schur decomposition of a square matrix.
Definition: RealSchur.h:54
void makeGivens(const Scalar &p, const Scalar &q, Scalar *z=0)
Definition: Jacobi.h:149
const Eigen::CwiseUnaryOp< Eigen::internal::scalar_sqrt_op< typename Derived::Scalar >, const Derived > sqrt(const Eigen::ArrayBase< Derived > &x)
RealSchur & computeFromHessenberg(const HessMatrixType &matrixH, const OrthMatrixType &matrixQ, bool computeU)
Computes Schur decomposition of a Hessenberg matrix H = Z T Z^T.
Namespace containing all symbols from the Eigen library.
Definition: Core:287
Rotation given by a cosine-sine pair.
Definition: ForwardDeclarations.h:263
Holds information about the various numeric (i.e. scalar) types allowed by Eigen. ...
Definition: NumTraits.h:150
Derived & derived()
Definition: EigenBase.h:45
RealSchur(Index size=RowsAtCompileTime==Dynamic ? 1 :RowsAtCompileTime)
Default constructor.
Definition: RealSchur.h:83
void resize(Index rows, Index cols)
Definition: PlainObjectBase.h:279
Index getMaxIterations()
Returns the maximum number of iterations.
Definition: RealSchur.h:213
Definition: EigenBase.h:29
Scalar & coeffRef(Index rowId, Index colId)
Definition: PlainObjectBase.h:183
Eigen::Index Index
Definition: RealSchur.h:67
HessenbergDecomposition & compute(const EigenBase< InputType > &matrix)
Computes Hessenberg decomposition of given matrix.
Definition: HessenbergDecomposition.h:152
Index rows() const
Definition: EigenBase.h:59
MatrixHReturnType matrixH() const
Constructs the Hessenberg matrix H in the decomposition.
Definition: HessenbergDecomposition.h:262
EIGEN_DEFAULT_DENSE_INDEX_TYPE Index
The Index type as used for the API.
Definition: Meta.h:33
static const int m_maxIterationsPerRow
Maximum number of iterations per row.
Definition: RealSchur.h:223
RealSchur & compute(const EigenBase< InputType > &matrix, bool computeU=true)
Computes Schur decomposition of given matrix.
Derived & setConstant(Index size, const Scalar &val)
Definition: CwiseNullaryOp.h:341
const MatrixType & matrixT() const
Returns the quasi-triangular matrix in the Schur decomposition.
Definition: RealSchur.h:144
Definition: Constants.h:432
const Eigen::CwiseUnaryOp< Eigen::internal::scalar_abs_op< typename Derived::Scalar >, const Derived > abs(const Eigen::ArrayBase< Derived > &x)
const MatrixType & matrixU() const
Returns the orthogonal matrix in the Schur decomposition.
Definition: RealSchur.h:127
const Scalar & coeff(Index rowId, Index colId) const
Definition: PlainObjectBase.h:160
RealSchur & setMaxIterations(Index maxIters)
Sets the maximum number of iterations allowed.
Definition: RealSchur.h:206
HouseholderSequenceType matrixQ() const
Reconstructs the orthogonal matrix Q in the decomposition.
Definition: HessenbergDecomposition.h:234
const int Dynamic
Definition: Constants.h:21
ComputationInfo info() const
Reports whether previous computation was successful.
Definition: RealSchur.h:195
RealSchur(const EigenBase< InputType > &matrix, bool computeU=true)
Constructor; computes real Schur decomposition of given matrix.
Definition: RealSchur.h:104
Index cols() const
Definition: EigenBase.h:62
ComputationInfo
Definition: Constants.h:430
Definition: Constants.h:436
JacobiRotation adjoint() const
Definition: Jacobi.h:62