--- rpl/lapack/lapack/zstemr.f 2010/04/21 13:45:38 1.2
+++ rpl/lapack/lapack/zstemr.f 2018/05/29 07:18:35 1.21
@@ -1,14 +1,347 @@
+*> \brief \b ZSTEMR
+*
+* =========== DOCUMENTATION ===========
+*
+* Online html documentation available at
+* http://www.netlib.org/lapack/explore-html/
+*
+*> \htmlonly
+*> Download ZSTEMR + dependencies
+*>
+*> [TGZ]
+*>
+*> [ZIP]
+*>
+*> [TXT]
+*> \endhtmlonly
+*
+* Definition:
+* ===========
+*
+* SUBROUTINE ZSTEMR( JOBZ, RANGE, N, D, E, VL, VU, IL, IU,
+* M, W, Z, LDZ, NZC, ISUPPZ, TRYRAC, WORK, LWORK,
+* IWORK, LIWORK, INFO )
+*
+* .. Scalar Arguments ..
+* CHARACTER JOBZ, RANGE
+* LOGICAL TRYRAC
+* INTEGER IL, INFO, IU, LDZ, NZC, LIWORK, LWORK, M, N
+* DOUBLE PRECISION VL, VU
+* ..
+* .. Array Arguments ..
+* INTEGER ISUPPZ( * ), IWORK( * )
+* DOUBLE PRECISION D( * ), E( * ), W( * ), WORK( * )
+* COMPLEX*16 Z( LDZ, * )
+* ..
+*
+*
+*> \par Purpose:
+* =============
+*>
+*> \verbatim
+*>
+*> ZSTEMR computes selected eigenvalues and, optionally, eigenvectors
+*> of a real symmetric tridiagonal matrix T. Any such unreduced matrix has
+*> a well defined set of pairwise different real eigenvalues, the corresponding
+*> real eigenvectors are pairwise orthogonal.
+*>
+*> The spectrum may be computed either completely or partially by specifying
+*> either an interval (VL,VU] or a range of indices IL:IU for the desired
+*> eigenvalues.
+*>
+*> Depending on the number of desired eigenvalues, these are computed either
+*> by bisection or the dqds algorithm. Numerically orthogonal eigenvectors are
+*> computed by the use of various suitable L D L^T factorizations near clusters
+*> of close eigenvalues (referred to as RRRs, Relatively Robust
+*> Representations). An informal sketch of the algorithm follows.
+*>
+*> For each unreduced block (submatrix) of T,
+*> (a) Compute T - sigma I = L D L^T, so that L and D
+*> define all the wanted eigenvalues to high relative accuracy.
+*> This means that small relative changes in the entries of D and L
+*> cause only small relative changes in the eigenvalues and
+*> eigenvectors. The standard (unfactored) representation of the
+*> tridiagonal matrix T does not have this property in general.
+*> (b) Compute the eigenvalues to suitable accuracy.
+*> If the eigenvectors are desired, the algorithm attains full
+*> accuracy of the computed eigenvalues only right before
+*> the corresponding vectors have to be computed, see steps c) and d).
+*> (c) For each cluster of close eigenvalues, select a new
+*> shift close to the cluster, find a new factorization, and refine
+*> the shifted eigenvalues to suitable accuracy.
+*> (d) For each eigenvalue with a large enough relative separation compute
+*> the corresponding eigenvector by forming a rank revealing twisted
+*> factorization. Go back to (c) for any clusters that remain.
+*>
+*> For more details, see:
+*> - Inderjit S. Dhillon and Beresford N. Parlett: "Multiple representations
+*> to compute orthogonal eigenvectors of symmetric tridiagonal matrices,"
+*> Linear Algebra and its Applications, 387(1), pp. 1-28, August 2004.
+*> - Inderjit Dhillon and Beresford Parlett: "Orthogonal Eigenvectors and
+*> Relative Gaps," SIAM Journal on Matrix Analysis and Applications, Vol. 25,
+*> 2004. Also LAPACK Working Note 154.
+*> - Inderjit Dhillon: "A new O(n^2) algorithm for the symmetric
+*> tridiagonal eigenvalue/eigenvector problem",
+*> Computer Science Division Technical Report No. UCB/CSD-97-971,
+*> UC Berkeley, May 1997.
+*>
+*> Further Details
+*> 1.ZSTEMR works only on machines which follow IEEE-754
+*> floating-point standard in their handling of infinities and NaNs.
+*> This permits the use of efficient inner loops avoiding a check for
+*> zero divisors.
+*>
+*> 2. LAPACK routines can be used to reduce a complex Hermitean matrix to
+*> real symmetric tridiagonal form.
+*>
+*> (Any complex Hermitean tridiagonal matrix has real values on its diagonal
+*> and potentially complex numbers on its off-diagonals. By applying a
+*> similarity transform with an appropriate diagonal matrix
+*> diag(1,e^{i \phy_1}, ... , e^{i \phy_{n-1}}), the complex Hermitean
+*> matrix can be transformed into a real symmetric matrix and complex
+*> arithmetic can be entirely avoided.)
+*>
+*> While the eigenvectors of the real symmetric tridiagonal matrix are real,
+*> the eigenvectors of original complex Hermitean matrix have complex entries
+*> in general.
+*> Since LAPACK drivers overwrite the matrix data with the eigenvectors,
+*> ZSTEMR accepts complex workspace to facilitate interoperability
+*> with ZUNMTR or ZUPMTR.
+*> \endverbatim
+*
+* Arguments:
+* ==========
+*
+*> \param[in] JOBZ
+*> \verbatim
+*> JOBZ is CHARACTER*1
+*> = 'N': Compute eigenvalues only;
+*> = 'V': Compute eigenvalues and eigenvectors.
+*> \endverbatim
+*>
+*> \param[in] RANGE
+*> \verbatim
+*> RANGE is CHARACTER*1
+*> = 'A': all eigenvalues will be found.
+*> = 'V': all eigenvalues in the half-open interval (VL,VU]
+*> will be found.
+*> = 'I': the IL-th through IU-th eigenvalues will be found.
+*> \endverbatim
+*>
+*> \param[in] N
+*> \verbatim
+*> N is INTEGER
+*> The order of the matrix. N >= 0.
+*> \endverbatim
+*>
+*> \param[in,out] D
+*> \verbatim
+*> D is DOUBLE PRECISION array, dimension (N)
+*> On entry, the N diagonal elements of the tridiagonal matrix
+*> T. On exit, D is overwritten.
+*> \endverbatim
+*>
+*> \param[in,out] E
+*> \verbatim
+*> E is DOUBLE PRECISION array, dimension (N)
+*> On entry, the (N-1) subdiagonal elements of the tridiagonal
+*> matrix T in elements 1 to N-1 of E. E(N) need not be set on
+*> input, but is used internally as workspace.
+*> On exit, E is overwritten.
+*> \endverbatim
+*>
+*> \param[in] VL
+*> \verbatim
+*> VL is DOUBLE PRECISION
+*>
+*> If RANGE='V', the lower bound of the interval to
+*> be searched for eigenvalues. VL < VU.
+*> Not referenced if RANGE = 'A' or 'I'.
+*> \endverbatim
+*>
+*> \param[in] VU
+*> \verbatim
+*> VU is DOUBLE PRECISION
+*>
+*> If RANGE='V', the upper bound of the interval to
+*> be searched for eigenvalues. VL < VU.
+*> Not referenced if RANGE = 'A' or 'I'.
+*> \endverbatim
+*>
+*> \param[in] IL
+*> \verbatim
+*> IL is INTEGER
+*>
+*> If RANGE='I', the index of the
+*> smallest eigenvalue to be returned.
+*> 1 <= IL <= IU <= N, if N > 0.
+*> Not referenced if RANGE = 'A' or 'V'.
+*> \endverbatim
+*>
+*> \param[in] IU
+*> \verbatim
+*> IU is INTEGER
+*>
+*> If RANGE='I', the index of the
+*> largest eigenvalue to be returned.
+*> 1 <= IL <= IU <= N, if N > 0.
+*> Not referenced if RANGE = 'A' or 'V'.
+*> \endverbatim
+*>
+*> \param[out] M
+*> \verbatim
+*> M is INTEGER
+*> The total number of eigenvalues found. 0 <= M <= N.
+*> If RANGE = 'A', M = N, and if RANGE = 'I', M = IU-IL+1.
+*> \endverbatim
+*>
+*> \param[out] W
+*> \verbatim
+*> W is DOUBLE PRECISION array, dimension (N)
+*> The first M elements contain the selected eigenvalues in
+*> ascending order.
+*> \endverbatim
+*>
+*> \param[out] Z
+*> \verbatim
+*> Z is COMPLEX*16 array, dimension (LDZ, max(1,M) )
+*> If JOBZ = 'V', and if INFO = 0, then the first M columns of Z
+*> contain the orthonormal eigenvectors of the matrix T
+*> corresponding to the selected eigenvalues, with the i-th
+*> column of Z holding the eigenvector associated with W(i).
+*> If JOBZ = 'N', then Z is not referenced.
+*> Note: the user must ensure that at least max(1,M) columns are
+*> supplied in the array Z; if RANGE = 'V', the exact value of M
+*> is not known in advance and can be computed with a workspace
+*> query by setting NZC = -1, see below.
+*> \endverbatim
+*>
+*> \param[in] LDZ
+*> \verbatim
+*> LDZ is INTEGER
+*> The leading dimension of the array Z. LDZ >= 1, and if
+*> JOBZ = 'V', then LDZ >= max(1,N).
+*> \endverbatim
+*>
+*> \param[in] NZC
+*> \verbatim
+*> NZC is INTEGER
+*> The number of eigenvectors to be held in the array Z.
+*> If RANGE = 'A', then NZC >= max(1,N).
+*> If RANGE = 'V', then NZC >= the number of eigenvalues in (VL,VU].
+*> If RANGE = 'I', then NZC >= IU-IL+1.
+*> If NZC = -1, then a workspace query is assumed; the
+*> routine calculates the number of columns of the array Z that
+*> are needed to hold the eigenvectors.
+*> This value is returned as the first entry of the Z array, and
+*> no error message related to NZC is issued by XERBLA.
+*> \endverbatim
+*>
+*> \param[out] ISUPPZ
+*> \verbatim
+*> ISUPPZ is INTEGER array, dimension ( 2*max(1,M) )
+*> The support of the eigenvectors in Z, i.e., the indices
+*> indicating the nonzero elements in Z. The i-th computed eigenvector
+*> is nonzero only in elements ISUPPZ( 2*i-1 ) through
+*> ISUPPZ( 2*i ). This is relevant in the case when the matrix
+*> is split. ISUPPZ is only accessed when JOBZ is 'V' and N > 0.
+*> \endverbatim
+*>
+*> \param[in,out] TRYRAC
+*> \verbatim
+*> TRYRAC is LOGICAL
+*> If TRYRAC.EQ..TRUE., indicates that the code should check whether
+*> the tridiagonal matrix defines its eigenvalues to high relative
+*> accuracy. If so, the code uses relative-accuracy preserving
+*> algorithms that might be (a bit) slower depending on the matrix.
+*> If the matrix does not define its eigenvalues to high relative
+*> accuracy, the code can uses possibly faster algorithms.
+*> If TRYRAC.EQ..FALSE., the code is not required to guarantee
+*> relatively accurate eigenvalues and can use the fastest possible
+*> techniques.
+*> On exit, a .TRUE. TRYRAC will be set to .FALSE. if the matrix
+*> does not define its eigenvalues to high relative accuracy.
+*> \endverbatim
+*>
+*> \param[out] WORK
+*> \verbatim
+*> WORK is DOUBLE PRECISION array, dimension (LWORK)
+*> On exit, if INFO = 0, WORK(1) returns the optimal
+*> (and minimal) LWORK.
+*> \endverbatim
+*>
+*> \param[in] LWORK
+*> \verbatim
+*> LWORK is INTEGER
+*> The dimension of the array WORK. LWORK >= max(1,18*N)
+*> if JOBZ = 'V', and LWORK >= max(1,12*N) if JOBZ = 'N'.
+*> If LWORK = -1, then a workspace query is assumed; the routine
+*> only calculates the optimal size of the WORK array, returns
+*> this value as the first entry of the WORK array, and no error
+*> message related to LWORK is issued by XERBLA.
+*> \endverbatim
+*>
+*> \param[out] IWORK
+*> \verbatim
+*> IWORK is INTEGER array, dimension (LIWORK)
+*> On exit, if INFO = 0, IWORK(1) returns the optimal LIWORK.
+*> \endverbatim
+*>
+*> \param[in] LIWORK
+*> \verbatim
+*> LIWORK is INTEGER
+*> The dimension of the array IWORK. LIWORK >= max(1,10*N)
+*> if the eigenvectors are desired, and LIWORK >= max(1,8*N)
+*> if only the eigenvalues are to be computed.
+*> If LIWORK = -1, then a workspace query is assumed; the
+*> routine only calculates the optimal size of the IWORK array,
+*> returns this value as the first entry of the IWORK array, and
+*> no error message related to LIWORK is issued by XERBLA.
+*> \endverbatim
+*>
+*> \param[out] INFO
+*> \verbatim
+*> INFO is INTEGER
+*> On exit, INFO
+*> = 0: successful exit
+*> < 0: if INFO = -i, the i-th argument had an illegal value
+*> > 0: if INFO = 1X, internal error in DLARRE,
+*> if INFO = 2X, internal error in ZLARRV.
+*> Here, the digit X = ABS( IINFO ) < 10, where IINFO is
+*> the nonzero error code returned by DLARRE or
+*> ZLARRV, respectively.
+*> \endverbatim
+*
+* Authors:
+* ========
+*
+*> \author Univ. of Tennessee
+*> \author Univ. of California Berkeley
+*> \author Univ. of Colorado Denver
+*> \author NAG Ltd.
+*
+*> \date June 2016
+*
+*> \ingroup complex16OTHERcomputational
+*
+*> \par Contributors:
+* ==================
+*>
+*> Beresford Parlett, University of California, Berkeley, USA \n
+*> Jim Demmel, University of California, Berkeley, USA \n
+*> Inderjit Dhillon, University of Texas, Austin, USA \n
+*> Osni Marques, LBNL/NERSC, USA \n
+*> Christof Voemel, University of California, Berkeley, USA \n
+*
+* =====================================================================
SUBROUTINE ZSTEMR( JOBZ, RANGE, N, D, E, VL, VU, IL, IU,
$ M, W, Z, LDZ, NZC, ISUPPZ, TRYRAC, WORK, LWORK,
$ IWORK, LIWORK, INFO )
- IMPLICIT NONE
-*
-* -- LAPACK computational routine (version 3.2.1) --
-*
-* -- April 2009 --
*
+* -- LAPACK computational routine (version 3.7.1) --
* -- LAPACK is a software package provided by Univ. of Tennessee, --
* -- Univ. of California Berkeley, Univ. of Colorado Denver and NAG Ltd..--
+* June 2016
*
* .. Scalar Arguments ..
CHARACTER JOBZ, RANGE
@@ -22,215 +355,6 @@
COMPLEX*16 Z( LDZ, * )
* ..
*
-* Purpose
-* =======
-*
-* ZSTEMR computes selected eigenvalues and, optionally, eigenvectors
-* of a real symmetric tridiagonal matrix T. Any such unreduced matrix has
-* a well defined set of pairwise different real eigenvalues, the corresponding
-* real eigenvectors are pairwise orthogonal.
-*
-* The spectrum may be computed either completely or partially by specifying
-* either an interval (VL,VU] or a range of indices IL:IU for the desired
-* eigenvalues.
-*
-* Depending on the number of desired eigenvalues, these are computed either
-* by bisection or the dqds algorithm. Numerically orthogonal eigenvectors are
-* computed by the use of various suitable L D L^T factorizations near clusters
-* of close eigenvalues (referred to as RRRs, Relatively Robust
-* Representations). An informal sketch of the algorithm follows.
-*
-* For each unreduced block (submatrix) of T,
-* (a) Compute T - sigma I = L D L^T, so that L and D
-* define all the wanted eigenvalues to high relative accuracy.
-* This means that small relative changes in the entries of D and L
-* cause only small relative changes in the eigenvalues and
-* eigenvectors. The standard (unfactored) representation of the
-* tridiagonal matrix T does not have this property in general.
-* (b) Compute the eigenvalues to suitable accuracy.
-* If the eigenvectors are desired, the algorithm attains full
-* accuracy of the computed eigenvalues only right before
-* the corresponding vectors have to be computed, see steps c) and d).
-* (c) For each cluster of close eigenvalues, select a new
-* shift close to the cluster, find a new factorization, and refine
-* the shifted eigenvalues to suitable accuracy.
-* (d) For each eigenvalue with a large enough relative separation compute
-* the corresponding eigenvector by forming a rank revealing twisted
-* factorization. Go back to (c) for any clusters that remain.
-*
-* For more details, see:
-* - Inderjit S. Dhillon and Beresford N. Parlett: "Multiple representations
-* to compute orthogonal eigenvectors of symmetric tridiagonal matrices,"
-* Linear Algebra and its Applications, 387(1), pp. 1-28, August 2004.
-* - Inderjit Dhillon and Beresford Parlett: "Orthogonal Eigenvectors and
-* Relative Gaps," SIAM Journal on Matrix Analysis and Applications, Vol. 25,
-* 2004. Also LAPACK Working Note 154.
-* - Inderjit Dhillon: "A new O(n^2) algorithm for the symmetric
-* tridiagonal eigenvalue/eigenvector problem",
-* Computer Science Division Technical Report No. UCB/CSD-97-971,
-* UC Berkeley, May 1997.
-*
-* Further Details
-* 1.ZSTEMR works only on machines which follow IEEE-754
-* floating-point standard in their handling of infinities and NaNs.
-* This permits the use of efficient inner loops avoiding a check for
-* zero divisors.
-*
-* 2. LAPACK routines can be used to reduce a complex Hermitean matrix to
-* real symmetric tridiagonal form.
-*
-* (Any complex Hermitean tridiagonal matrix has real values on its diagonal
-* and potentially complex numbers on its off-diagonals. By applying a
-* similarity transform with an appropriate diagonal matrix
-* diag(1,e^{i \phy_1}, ... , e^{i \phy_{n-1}}), the complex Hermitean
-* matrix can be transformed into a real symmetric matrix and complex
-* arithmetic can be entirely avoided.)
-*
-* While the eigenvectors of the real symmetric tridiagonal matrix are real,
-* the eigenvectors of original complex Hermitean matrix have complex entries
-* in general.
-* Since LAPACK drivers overwrite the matrix data with the eigenvectors,
-* ZSTEMR accepts complex workspace to facilitate interoperability
-* with ZUNMTR or ZUPMTR.
-*
-* Arguments
-* =========
-*
-* JOBZ (input) CHARACTER*1
-* = 'N': Compute eigenvalues only;
-* = 'V': Compute eigenvalues and eigenvectors.
-*
-* RANGE (input) CHARACTER*1
-* = 'A': all eigenvalues will be found.
-* = 'V': all eigenvalues in the half-open interval (VL,VU]
-* will be found.
-* = 'I': the IL-th through IU-th eigenvalues will be found.
-*
-* N (input) INTEGER
-* The order of the matrix. N >= 0.
-*
-* D (input/output) DOUBLE PRECISION array, dimension (N)
-* On entry, the N diagonal elements of the tridiagonal matrix
-* T. On exit, D is overwritten.
-*
-* E (input/output) DOUBLE PRECISION array, dimension (N)
-* On entry, the (N-1) subdiagonal elements of the tridiagonal
-* matrix T in elements 1 to N-1 of E. E(N) need not be set on
-* input, but is used internally as workspace.
-* On exit, E is overwritten.
-*
-* VL (input) DOUBLE PRECISION
-* VU (input) DOUBLE PRECISION
-* If RANGE='V', the lower and upper bounds of the interval to
-* be searched for eigenvalues. VL < VU.
-* Not referenced if RANGE = 'A' or 'I'.
-*
-* IL (input) INTEGER
-* IU (input) INTEGER
-* If RANGE='I', the indices (in ascending order) of the
-* smallest and largest eigenvalues to be returned.
-* 1 <= IL <= IU <= N, if N > 0.
-* Not referenced if RANGE = 'A' or 'V'.
-*
-* M (output) INTEGER
-* The total number of eigenvalues found. 0 <= M <= N.
-* If RANGE = 'A', M = N, and if RANGE = 'I', M = IU-IL+1.
-*
-* W (output) DOUBLE PRECISION array, dimension (N)
-* The first M elements contain the selected eigenvalues in
-* ascending order.
-*
-* Z (output) COMPLEX*16 array, dimension (LDZ, max(1,M) )
-* If JOBZ = 'V', and if INFO = 0, then the first M columns of Z
-* contain the orthonormal eigenvectors of the matrix T
-* corresponding to the selected eigenvalues, with the i-th
-* column of Z holding the eigenvector associated with W(i).
-* If JOBZ = 'N', then Z is not referenced.
-* Note: the user must ensure that at least max(1,M) columns are
-* supplied in the array Z; if RANGE = 'V', the exact value of M
-* is not known in advance and can be computed with a workspace
-* query by setting NZC = -1, see below.
-*
-* LDZ (input) INTEGER
-* The leading dimension of the array Z. LDZ >= 1, and if
-* JOBZ = 'V', then LDZ >= max(1,N).
-*
-* NZC (input) INTEGER
-* The number of eigenvectors to be held in the array Z.
-* If RANGE = 'A', then NZC >= max(1,N).
-* If RANGE = 'V', then NZC >= the number of eigenvalues in (VL,VU].
-* If RANGE = 'I', then NZC >= IU-IL+1.
-* If NZC = -1, then a workspace query is assumed; the
-* routine calculates the number of columns of the array Z that
-* are needed to hold the eigenvectors.
-* This value is returned as the first entry of the Z array, and
-* no error message related to NZC is issued by XERBLA.
-*
-* ISUPPZ (output) INTEGER ARRAY, dimension ( 2*max(1,M) )
-* The support of the eigenvectors in Z, i.e., the indices
-* indicating the nonzero elements in Z. The i-th computed eigenvector
-* is nonzero only in elements ISUPPZ( 2*i-1 ) through
-* ISUPPZ( 2*i ). This is relevant in the case when the matrix
-* is split. ISUPPZ is only accessed when JOBZ is 'V' and N > 0.
-*
-* TRYRAC (input/output) LOGICAL
-* If TRYRAC.EQ..TRUE., indicates that the code should check whether
-* the tridiagonal matrix defines its eigenvalues to high relative
-* accuracy. If so, the code uses relative-accuracy preserving
-* algorithms that might be (a bit) slower depending on the matrix.
-* If the matrix does not define its eigenvalues to high relative
-* accuracy, the code can uses possibly faster algorithms.
-* If TRYRAC.EQ..FALSE., the code is not required to guarantee
-* relatively accurate eigenvalues and can use the fastest possible
-* techniques.
-* On exit, a .TRUE. TRYRAC will be set to .FALSE. if the matrix
-* does not define its eigenvalues to high relative accuracy.
-*
-* WORK (workspace/output) DOUBLE PRECISION array, dimension (LWORK)
-* On exit, if INFO = 0, WORK(1) returns the optimal
-* (and minimal) LWORK.
-*
-* LWORK (input) INTEGER
-* The dimension of the array WORK. LWORK >= max(1,18*N)
-* if JOBZ = 'V', and LWORK >= max(1,12*N) if JOBZ = 'N'.
-* If LWORK = -1, then a workspace query is assumed; the routine
-* only calculates the optimal size of the WORK array, returns
-* this value as the first entry of the WORK array, and no error
-* message related to LWORK is issued by XERBLA.
-*
-* IWORK (workspace/output) INTEGER array, dimension (LIWORK)
-* On exit, if INFO = 0, IWORK(1) returns the optimal LIWORK.
-*
-* LIWORK (input) INTEGER
-* The dimension of the array IWORK. LIWORK >= max(1,10*N)
-* if the eigenvectors are desired, and LIWORK >= max(1,8*N)
-* if only the eigenvalues are to be computed.
-* If LIWORK = -1, then a workspace query is assumed; the
-* routine only calculates the optimal size of the IWORK array,
-* returns this value as the first entry of the IWORK array, and
-* no error message related to LIWORK is issued by XERBLA.
-*
-* INFO (output) INTEGER
-* On exit, INFO
-* = 0: successful exit
-* < 0: if INFO = -i, the i-th argument had an illegal value
-* > 0: if INFO = 1X, internal error in DLARRE,
-* if INFO = 2X, internal error in ZLARRV.
-* Here, the digit X = ABS( IINFO ) < 10, where IINFO is
-* the nonzero error code returned by DLARRE or
-* ZLARRV, respectively.
-*
-*
-* Further Details
-* ===============
-*
-* Based on contributions by
-* Beresford Parlett, University of California, Berkeley, USA
-* Jim Demmel, University of California, Berkeley, USA
-* Inderjit Dhillon, University of Texas, Austin, USA
-* Osni Marques, LBNL/NERSC, USA
-* Christof Voemel, University of California, Berkeley, USA
-*
* =====================================================================
*
* .. Parameters ..
@@ -293,6 +417,7 @@
WU = ZERO
IIL = 0
IIU = 0
+ NSPLIT = 0
IF( VALEIG ) THEN
* We do not reference VL, VU in the cases RANGE = 'I','A'
@@ -410,10 +535,10 @@
IF (SN.NE.ZERO) THEN
IF (CS.NE.ZERO) THEN
ISUPPZ(2*M-1) = 1
- ISUPPZ(2*M-1) = 2
+ ISUPPZ(2*M) = 2
ELSE
ISUPPZ(2*M-1) = 1
- ISUPPZ(2*M-1) = 1
+ ISUPPZ(2*M) = 1
END IF
ELSE
ISUPPZ(2*M-1) = 2
@@ -434,10 +559,10 @@
IF (SN.NE.ZERO) THEN
IF (CS.NE.ZERO) THEN
ISUPPZ(2*M-1) = 1
- ISUPPZ(2*M-1) = 2
+ ISUPPZ(2*M) = 2
ELSE
ISUPPZ(2*M-1) = 1
- ISUPPZ(2*M-1) = 1
+ ISUPPZ(2*M) = 1
END IF
ELSE
ISUPPZ(2*M-1) = 2
@@ -445,184 +570,184 @@
END IF
ENDIF
ENDIF
- RETURN
- END IF
+ ELSE
-* Continue with general N
+* Continue with general N
- INDGRS = 1
- INDERR = 2*N + 1
- INDGP = 3*N + 1
- INDD = 4*N + 1
- INDE2 = 5*N + 1
- INDWRK = 6*N + 1
-*
- IINSPL = 1
- IINDBL = N + 1
- IINDW = 2*N + 1
- IINDWK = 3*N + 1
-*
-* Scale matrix to allowable range, if necessary.
-* The allowable range is related to the PIVMIN parameter; see the
-* comments in DLARRD. The preference for scaling small values
-* up is heuristic; we expect users' matrices not to be close to the
-* RMAX threshold.
-*
- SCALE = ONE
- TNRM = DLANST( 'M', N, D, E )
- IF( TNRM.GT.ZERO .AND. TNRM.LT.RMIN ) THEN
- SCALE = RMIN / TNRM
- ELSE IF( TNRM.GT.RMAX ) THEN
- SCALE = RMAX / TNRM
- END IF
- IF( SCALE.NE.ONE ) THEN
- CALL DSCAL( N, SCALE, D, 1 )
- CALL DSCAL( N-1, SCALE, E, 1 )
- TNRM = TNRM*SCALE
- IF( VALEIG ) THEN
-* If eigenvalues in interval have to be found,
-* scale (WL, WU] accordingly
- WL = WL*SCALE
- WU = WU*SCALE
- ENDIF
- END IF
+ INDGRS = 1
+ INDERR = 2*N + 1
+ INDGP = 3*N + 1
+ INDD = 4*N + 1
+ INDE2 = 5*N + 1
+ INDWRK = 6*N + 1
+*
+ IINSPL = 1
+ IINDBL = N + 1
+ IINDW = 2*N + 1
+ IINDWK = 3*N + 1
+*
+* Scale matrix to allowable range, if necessary.
+* The allowable range is related to the PIVMIN parameter; see the
+* comments in DLARRD. The preference for scaling small values
+* up is heuristic; we expect users' matrices not to be close to the
+* RMAX threshold.
+*
+ SCALE = ONE
+ TNRM = DLANST( 'M', N, D, E )
+ IF( TNRM.GT.ZERO .AND. TNRM.LT.RMIN ) THEN
+ SCALE = RMIN / TNRM
+ ELSE IF( TNRM.GT.RMAX ) THEN
+ SCALE = RMAX / TNRM
+ END IF
+ IF( SCALE.NE.ONE ) THEN
+ CALL DSCAL( N, SCALE, D, 1 )
+ CALL DSCAL( N-1, SCALE, E, 1 )
+ TNRM = TNRM*SCALE
+ IF( VALEIG ) THEN
+* If eigenvalues in interval have to be found,
+* scale (WL, WU] accordingly
+ WL = WL*SCALE
+ WU = WU*SCALE
+ ENDIF
+ END IF
*
-* Compute the desired eigenvalues of the tridiagonal after splitting
-* into smaller subblocks if the corresponding off-diagonal elements
-* are small
-* THRESH is the splitting parameter for DLARRE
-* A negative THRESH forces the old splitting criterion based on the
-* size of the off-diagonal. A positive THRESH switches to splitting
-* which preserves relative accuracy.
-*
- IF( TRYRAC ) THEN
-* Test whether the matrix warrants the more expensive relative approach.
- CALL DLARRR( N, D, E, IINFO )
- ELSE
-* The user does not care about relative accurately eigenvalues
- IINFO = -1
- ENDIF
-* Set the splitting criterion
- IF (IINFO.EQ.0) THEN
- THRESH = EPS
- ELSE
- THRESH = -EPS
-* relative accuracy is desired but T does not guarantee it
- TRYRAC = .FALSE.
- ENDIF
+* Compute the desired eigenvalues of the tridiagonal after splitting
+* into smaller subblocks if the corresponding off-diagonal elements
+* are small
+* THRESH is the splitting parameter for DLARRE
+* A negative THRESH forces the old splitting criterion based on the
+* size of the off-diagonal. A positive THRESH switches to splitting
+* which preserves relative accuracy.
+*
+ IF( TRYRAC ) THEN
+* Test whether the matrix warrants the more expensive relative approach.
+ CALL DLARRR( N, D, E, IINFO )
+ ELSE
+* The user does not care about relative accurately eigenvalues
+ IINFO = -1
+ ENDIF
+* Set the splitting criterion
+ IF (IINFO.EQ.0) THEN
+ THRESH = EPS
+ ELSE
+ THRESH = -EPS
+* relative accuracy is desired but T does not guarantee it
+ TRYRAC = .FALSE.
+ ENDIF
*
- IF( TRYRAC ) THEN
-* Copy original diagonal, needed to guarantee relative accuracy
- CALL DCOPY(N,D,1,WORK(INDD),1)
- ENDIF
-* Store the squares of the offdiagonal values of T
- DO 5 J = 1, N-1
- WORK( INDE2+J-1 ) = E(J)**2
+ IF( TRYRAC ) THEN
+* Copy original diagonal, needed to guarantee relative accuracy
+ CALL DCOPY(N,D,1,WORK(INDD),1)
+ ENDIF
+* Store the squares of the offdiagonal values of T
+ DO 5 J = 1, N-1
+ WORK( INDE2+J-1 ) = E(J)**2
5 CONTINUE
-* Set the tolerance parameters for bisection
- IF( .NOT.WANTZ ) THEN
-* DLARRE computes the eigenvalues to full precision.
- RTOL1 = FOUR * EPS
- RTOL2 = FOUR * EPS
- ELSE
-* DLARRE computes the eigenvalues to less than full precision.
-* ZLARRV will refine the eigenvalue approximations, and we only
-* need less accurate initial bisection in DLARRE.
-* Note: these settings do only affect the subset case and DLARRE
- RTOL1 = SQRT(EPS)
- RTOL2 = MAX( SQRT(EPS)*5.0D-3, FOUR * EPS )
- ENDIF
- CALL DLARRE( RANGE, N, WL, WU, IIL, IIU, D, E,
+* Set the tolerance parameters for bisection
+ IF( .NOT.WANTZ ) THEN
+* DLARRE computes the eigenvalues to full precision.
+ RTOL1 = FOUR * EPS
+ RTOL2 = FOUR * EPS
+ ELSE
+* DLARRE computes the eigenvalues to less than full precision.
+* ZLARRV will refine the eigenvalue approximations, and we only
+* need less accurate initial bisection in DLARRE.
+* Note: these settings do only affect the subset case and DLARRE
+ RTOL1 = SQRT(EPS)
+ RTOL2 = MAX( SQRT(EPS)*5.0D-3, FOUR * EPS )
+ ENDIF
+ CALL DLARRE( RANGE, N, WL, WU, IIL, IIU, D, E,
$ WORK(INDE2), RTOL1, RTOL2, THRESH, NSPLIT,
$ IWORK( IINSPL ), M, W, WORK( INDERR ),
$ WORK( INDGP ), IWORK( IINDBL ),
$ IWORK( IINDW ), WORK( INDGRS ), PIVMIN,
$ WORK( INDWRK ), IWORK( IINDWK ), IINFO )
- IF( IINFO.NE.0 ) THEN
- INFO = 10 + ABS( IINFO )
- RETURN
- END IF
-* Note that if RANGE .NE. 'V', DLARRE computes bounds on the desired
-* part of the spectrum. All desired eigenvalues are contained in
-* (WL,WU]
+ IF( IINFO.NE.0 ) THEN
+ INFO = 10 + ABS( IINFO )
+ RETURN
+ END IF
+* Note that if RANGE .NE. 'V', DLARRE computes bounds on the desired
+* part of the spectrum. All desired eigenvalues are contained in
+* (WL,WU]
- IF( WANTZ ) THEN
+ IF( WANTZ ) THEN
*
-* Compute the desired eigenvectors corresponding to the computed
-* eigenvalues
+* Compute the desired eigenvectors corresponding to the computed
+* eigenvalues
*
- CALL ZLARRV( N, WL, WU, D, E,
+ CALL ZLARRV( N, WL, WU, D, E,
$ PIVMIN, IWORK( IINSPL ), M,
$ 1, M, MINRGP, RTOL1, RTOL2,
$ W, WORK( INDERR ), WORK( INDGP ), IWORK( IINDBL ),
$ IWORK( IINDW ), WORK( INDGRS ), Z, LDZ,
$ ISUPPZ, WORK( INDWRK ), IWORK( IINDWK ), IINFO )
- IF( IINFO.NE.0 ) THEN
- INFO = 20 + ABS( IINFO )
- RETURN
- END IF
- ELSE
-* DLARRE computes eigenvalues of the (shifted) root representation
-* ZLARRV returns the eigenvalues of the unshifted matrix.
-* However, if the eigenvectors are not desired by the user, we need
-* to apply the corresponding shifts from DLARRE to obtain the
-* eigenvalues of the original matrix.
- DO 20 J = 1, M
- ITMP = IWORK( IINDBL+J-1 )
- W( J ) = W( J ) + E( IWORK( IINSPL+ITMP-1 ) )
+ IF( IINFO.NE.0 ) THEN
+ INFO = 20 + ABS( IINFO )
+ RETURN
+ END IF
+ ELSE
+* DLARRE computes eigenvalues of the (shifted) root representation
+* ZLARRV returns the eigenvalues of the unshifted matrix.
+* However, if the eigenvectors are not desired by the user, we need
+* to apply the corresponding shifts from DLARRE to obtain the
+* eigenvalues of the original matrix.
+ DO 20 J = 1, M
+ ITMP = IWORK( IINDBL+J-1 )
+ W( J ) = W( J ) + E( IWORK( IINSPL+ITMP-1 ) )
20 CONTINUE
- END IF
+ END IF
*
- IF ( TRYRAC ) THEN
-* Refine computed eigenvalues so that they are relatively accurate
-* with respect to the original matrix T.
- IBEGIN = 1
- WBEGIN = 1
- DO 39 JBLK = 1, IWORK( IINDBL+M-1 )
- IEND = IWORK( IINSPL+JBLK-1 )
- IN = IEND - IBEGIN + 1
- WEND = WBEGIN - 1
-* check if any eigenvalues have to be refined in this block
+ IF ( TRYRAC ) THEN
+* Refine computed eigenvalues so that they are relatively accurate
+* with respect to the original matrix T.
+ IBEGIN = 1
+ WBEGIN = 1
+ DO 39 JBLK = 1, IWORK( IINDBL+M-1 )
+ IEND = IWORK( IINSPL+JBLK-1 )
+ IN = IEND - IBEGIN + 1
+ WEND = WBEGIN - 1
+* check if any eigenvalues have to be refined in this block
36 CONTINUE
- IF( WEND.LT.M ) THEN
- IF( IWORK( IINDBL+WEND ).EQ.JBLK ) THEN
- WEND = WEND + 1
- GO TO 36
+ IF( WEND.LT.M ) THEN
+ IF( IWORK( IINDBL+WEND ).EQ.JBLK ) THEN
+ WEND = WEND + 1
+ GO TO 36
+ END IF
+ END IF
+ IF( WEND.LT.WBEGIN ) THEN
+ IBEGIN = IEND + 1
+ GO TO 39
END IF
- END IF
- IF( WEND.LT.WBEGIN ) THEN
- IBEGIN = IEND + 1
- GO TO 39
- END IF
- OFFSET = IWORK(IINDW+WBEGIN-1)-1
- IFIRST = IWORK(IINDW+WBEGIN-1)
- ILAST = IWORK(IINDW+WEND-1)
- RTOL2 = FOUR * EPS
- CALL DLARRJ( IN,
+ OFFSET = IWORK(IINDW+WBEGIN-1)-1
+ IFIRST = IWORK(IINDW+WBEGIN-1)
+ ILAST = IWORK(IINDW+WEND-1)
+ RTOL2 = FOUR * EPS
+ CALL DLARRJ( IN,
$ WORK(INDD+IBEGIN-1), WORK(INDE2+IBEGIN-1),
$ IFIRST, ILAST, RTOL2, OFFSET, W(WBEGIN),
$ WORK( INDERR+WBEGIN-1 ),
$ WORK( INDWRK ), IWORK( IINDWK ), PIVMIN,
$ TNRM, IINFO )
- IBEGIN = IEND + 1
- WBEGIN = WEND + 1
+ IBEGIN = IEND + 1
+ WBEGIN = WEND + 1
39 CONTINUE
- ENDIF
+ ENDIF
*
-* If matrix was scaled, then rescale eigenvalues appropriately.
+* If matrix was scaled, then rescale eigenvalues appropriately.
*
- IF( SCALE.NE.ONE ) THEN
- CALL DSCAL( M, ONE / SCALE, W, 1 )
+ IF( SCALE.NE.ONE ) THEN
+ CALL DSCAL( M, ONE / SCALE, W, 1 )
+ END IF
END IF
*
* If eigenvalues are not in increasing order, then sort them,
* possibly along with eigenvectors.
*
- IF( NSPLIT.GT.1 ) THEN
+ IF( NSPLIT.GT.1 .OR. N.EQ.2 ) THEN
IF( .NOT. WANTZ ) THEN
CALL DLASRT( 'I', M, W, IINFO )
IF( IINFO.NE.0 ) THEN