Annotation of rpl/lapack/lapack/dbdsvdx.f, revision 1.9
1.1 bertrand 1: *> \brief \b DBDSVDX
2: *
3: * =========== DOCUMENTATION ===========
4: *
1.4 bertrand 5: * Online html documentation available at
6: * http://www.netlib.org/lapack/explore-html/
1.1 bertrand 7: *
8: *> \htmlonly
1.4 bertrand 9: *> Download DBDSVDX + dependencies
10: *> <a href="http://www.netlib.org/cgi-bin/netlibfiles.tgz?format=tgz&filename=/lapack/lapack_routine/dbdsvdx.f">
11: *> [TGZ]</a>
12: *> <a href="http://www.netlib.org/cgi-bin/netlibfiles.zip?format=zip&filename=/lapack/lapack_routine/dbdsvdx.f">
13: *> [ZIP]</a>
14: *> <a href="http://www.netlib.org/cgi-bin/netlibfiles.txt?format=txt&filename=/lapack/lapack_routine/dbdsvdx.f">
1.1 bertrand 15: *> [TXT]</a>
1.4 bertrand 16: *> \endhtmlonly
1.1 bertrand 17: *
18: * Definition:
19: * ===========
20: *
1.4 bertrand 21: * SUBROUTINE DBDSVDX( UPLO, JOBZ, RANGE, N, D, E, VL, VU, IL, IU,
1.1 bertrand 22: * $ NS, S, Z, LDZ, WORK, IWORK, INFO )
23: *
24: * .. Scalar Arguments ..
25: * CHARACTER JOBZ, RANGE, UPLO
26: * INTEGER IL, INFO, IU, LDZ, N, NS
27: * DOUBLE PRECISION VL, VU
28: * ..
29: * .. Array Arguments ..
30: * INTEGER IWORK( * )
1.4 bertrand 31: * DOUBLE PRECISION D( * ), E( * ), S( * ), WORK( * ),
1.1 bertrand 32: * Z( LDZ, * )
33: * ..
1.4 bertrand 34: *
1.1 bertrand 35: *> \par Purpose:
36: * =============
37: *>
38: *> \verbatim
39: *>
40: *> DBDSVDX computes the singular value decomposition (SVD) of a real
1.4 bertrand 41: *> N-by-N (upper or lower) bidiagonal matrix B, B = U * S * VT,
42: *> where S is a diagonal matrix with non-negative diagonal elements
43: *> (the singular values of B), and U and VT are orthogonal matrices
1.1 bertrand 44: *> of left and right singular vectors, respectively.
45: *>
1.4 bertrand 46: *> Given an upper bidiagonal B with diagonal D = [ d_1 d_2 ... d_N ]
47: *> and superdiagonal E = [ e_1 e_2 ... e_N-1 ], DBDSVDX computes the
48: *> singular value decompositon of B through the eigenvalues and
1.1 bertrand 49: *> eigenvectors of the N*2-by-N*2 tridiagonal matrix
1.4 bertrand 50: *>
51: *> | 0 d_1 |
52: *> | d_1 0 e_1 |
53: *> TGK = | e_1 0 d_2 |
54: *> | d_2 . . |
1.1 bertrand 55: *> | . . . |
56: *>
1.4 bertrand 57: *> If (s,u,v) is a singular triplet of B with ||u|| = ||v|| = 1, then
58: *> (+/-s,q), ||q|| = 1, are eigenpairs of TGK, with q = P * ( u' +/-v' ) /
59: *> sqrt(2) = ( v_1 u_1 v_2 u_2 ... v_n u_n ) / sqrt(2), and
60: *> P = [ e_{n+1} e_{1} e_{n+2} e_{2} ... ].
61: *>
62: *> Given a TGK matrix, one can either a) compute -s,-v and change signs
63: *> so that the singular values (and corresponding vectors) are already in
64: *> descending order (as in DGESVD/DGESDD) or b) compute s,v and reorder
65: *> the values (and corresponding vectors). DBDSVDX implements a) by
66: *> calling DSTEVX (bisection plus inverse iteration, to be replaced
67: *> with a version of the Multiple Relative Robust Representation
68: *> algorithm. (See P. Willems and B. Lang, A framework for the MR^3
69: *> algorithm: theory and implementation, SIAM J. Sci. Comput.,
1.1 bertrand 70: *> 35:740-766, 2013.)
71: *> \endverbatim
72: *
73: * Arguments:
74: * ==========
75: *
76: *> \param[in] UPLO
77: *> \verbatim
78: *> UPLO is CHARACTER*1
79: *> = 'U': B is upper bidiagonal;
80: *> = 'L': B is lower bidiagonal.
81: *> \endverbatim
82: *>
1.2 bertrand 83: *> \param[in] JOBZ
1.1 bertrand 84: *> \verbatim
85: *> JOBZ is CHARACTER*1
86: *> = 'N': Compute singular values only;
87: *> = 'V': Compute singular values and singular vectors.
88: *> \endverbatim
89: *>
90: *> \param[in] RANGE
91: *> \verbatim
92: *> RANGE is CHARACTER*1
93: *> = 'A': all singular values will be found.
94: *> = 'V': all singular values in the half-open interval [VL,VU)
95: *> will be found.
96: *> = 'I': the IL-th through IU-th singular values will be found.
97: *> \endverbatim
98: *>
99: *> \param[in] N
100: *> \verbatim
101: *> N is INTEGER
102: *> The order of the bidiagonal matrix. N >= 0.
103: *> \endverbatim
1.4 bertrand 104: *>
1.1 bertrand 105: *> \param[in] D
106: *> \verbatim
107: *> D is DOUBLE PRECISION array, dimension (N)
108: *> The n diagonal elements of the bidiagonal matrix B.
109: *> \endverbatim
1.4 bertrand 110: *>
1.1 bertrand 111: *> \param[in] E
112: *> \verbatim
113: *> E is DOUBLE PRECISION array, dimension (max(1,N-1))
114: *> The (n-1) superdiagonal elements of the bidiagonal matrix
115: *> B in elements 1 to N-1.
116: *> \endverbatim
117: *>
118: *> \param[in] VL
119: *> \verbatim
1.2 bertrand 120: *> VL is DOUBLE PRECISION
121: *> If RANGE='V', the lower bound of the interval to
122: *> be searched for singular values. VU > VL.
123: *> Not referenced if RANGE = 'A' or 'I'.
1.1 bertrand 124: *> \endverbatim
125: *>
126: *> \param[in] VU
127: *> \verbatim
128: *> VU is DOUBLE PRECISION
1.2 bertrand 129: *> If RANGE='V', the upper bound of the interval to
1.1 bertrand 130: *> be searched for singular values. VU > VL.
131: *> Not referenced if RANGE = 'A' or 'I'.
132: *> \endverbatim
133: *>
134: *> \param[in] IL
135: *> \verbatim
136: *> IL is INTEGER
1.2 bertrand 137: *> If RANGE='I', the index of the
138: *> smallest singular value to be returned.
139: *> 1 <= IL <= IU <= min(M,N), if min(M,N) > 0.
140: *> Not referenced if RANGE = 'A' or 'V'.
1.1 bertrand 141: *> \endverbatim
142: *>
143: *> \param[in] IU
144: *> \verbatim
145: *> IU is INTEGER
1.2 bertrand 146: *> If RANGE='I', the index of the
147: *> largest singular value to be returned.
1.1 bertrand 148: *> 1 <= IL <= IU <= min(M,N), if min(M,N) > 0.
149: *> Not referenced if RANGE = 'A' or 'V'.
150: *> \endverbatim
151: *>
152: *> \param[out] NS
153: *> \verbatim
154: *> NS is INTEGER
155: *> The total number of singular values found. 0 <= NS <= N.
156: *> If RANGE = 'A', NS = N, and if RANGE = 'I', NS = IU-IL+1.
157: *> \endverbatim
158: *>
159: *> \param[out] S
160: *> \verbatim
161: *> S is DOUBLE PRECISION array, dimension (N)
162: *> The first NS elements contain the selected singular values in
163: *> ascending order.
164: *> \endverbatim
165: *>
166: *> \param[out] Z
167: *> \verbatim
1.8 bertrand 168: *> Z is DOUBLE PRECISION array, dimension (2*N,K)
1.1 bertrand 169: *> If JOBZ = 'V', then if INFO = 0 the first NS columns of Z
1.4 bertrand 170: *> contain the singular vectors of the matrix B corresponding to
1.1 bertrand 171: *> the selected singular values, with U in rows 1 to N and V
172: *> in rows N+1 to N*2, i.e.
1.4 bertrand 173: *> Z = [ U ]
1.1 bertrand 174: *> [ V ]
1.4 bertrand 175: *> If JOBZ = 'N', then Z is not referenced.
176: *> Note: The user must ensure that at least K = NS+1 columns are
177: *> supplied in the array Z; if RANGE = 'V', the exact value of
1.1 bertrand 178: *> NS is not known in advance and an upper bound must be used.
179: *> \endverbatim
180: *>
181: *> \param[in] LDZ
182: *> \verbatim
183: *> LDZ is INTEGER
184: *> The leading dimension of the array Z. LDZ >= 1, and if
185: *> JOBZ = 'V', LDZ >= max(2,N*2).
186: *> \endverbatim
187: *>
188: *> \param[out] WORK
189: *> \verbatim
190: *> WORK is DOUBLE PRECISION array, dimension (14*N)
191: *> \endverbatim
192: *>
193: *> \param[out] IWORK
194: *> \verbatim
195: *> IWORK is INTEGER array, dimension (12*N)
196: *> If JOBZ = 'V', then if INFO = 0, the first NS elements of
1.4 bertrand 197: *> IWORK are zero. If INFO > 0, then IWORK contains the indices
1.1 bertrand 198: *> of the eigenvectors that failed to converge in DSTEVX.
1.2 bertrand 199: *> \endverbatim
1.1 bertrand 200: *>
1.2 bertrand 201: *> \param[out] INFO
202: *> \verbatim
1.1 bertrand 203: *> INFO is INTEGER
204: *> = 0: successful exit
205: *> < 0: if INFO = -i, the i-th argument had an illegal value
206: *> > 0: if INFO = i, then i eigenvectors failed to converge
207: *> in DSTEVX. The indices of the eigenvectors
208: *> (as returned by DSTEVX) are stored in the
209: *> array IWORK.
210: *> if INFO = N*2 + 1, an internal error occurred.
211: *> \endverbatim
212: *
213: * Authors:
214: * ========
215: *
1.4 bertrand 216: *> \author Univ. of Tennessee
217: *> \author Univ. of California Berkeley
218: *> \author Univ. of Colorado Denver
219: *> \author NAG Ltd.
1.1 bertrand 220: *
221: *> \ingroup doubleOTHEReigen
222: *
1.4 bertrand 223: * =====================================================================
224: SUBROUTINE DBDSVDX( UPLO, JOBZ, RANGE, N, D, E, VL, VU, IL, IU,
1.1 bertrand 225: $ NS, S, Z, LDZ, WORK, IWORK, INFO)
226: *
1.9 ! bertrand 227: * -- LAPACK driver routine --
1.1 bertrand 228: * -- LAPACK is a software package provided by Univ. of Tennessee, --
229: * -- Univ. of California Berkeley, Univ. of Colorado Denver and NAG Ltd..--
1.4 bertrand 230: *
1.1 bertrand 231: * .. Scalar Arguments ..
232: CHARACTER JOBZ, RANGE, UPLO
233: INTEGER IL, INFO, IU, LDZ, N, NS
234: DOUBLE PRECISION VL, VU
235: * ..
236: * .. Array Arguments ..
237: INTEGER IWORK( * )
1.4 bertrand 238: DOUBLE PRECISION D( * ), E( * ), S( * ), WORK( * ),
1.1 bertrand 239: $ Z( LDZ, * )
240: * ..
241: *
242: * =====================================================================
243: *
244: * .. Parameters ..
1.4 bertrand 245: DOUBLE PRECISION ZERO, ONE, TEN, HNDRD, MEIGTH
246: PARAMETER ( ZERO = 0.0D0, ONE = 1.0D0, TEN = 10.0D0,
1.1 bertrand 247: $ HNDRD = 100.0D0, MEIGTH = -0.1250D0 )
248: DOUBLE PRECISION FUDGE
249: PARAMETER ( FUDGE = 2.0D0 )
250: * ..
1.4 bertrand 251: * .. Local Scalars ..
1.1 bertrand 252: CHARACTER RNGVX
1.4 bertrand 253: LOGICAL ALLSV, INDSV, LOWER, SPLIT, SVEQ0, VALSV, WANTZ
254: INTEGER I, ICOLZ, IDBEG, IDEND, IDTGK, IDPTR, IEPTR,
255: $ IETGK, IIFAIL, IIWORK, ILTGK, IROWU, IROWV,
256: $ IROWZ, ISBEG, ISPLT, ITEMP, IUTGK, J, K,
1.1 bertrand 257: $ NTGK, NRU, NRV, NSL
258: DOUBLE PRECISION ABSTOL, EPS, EMIN, MU, NRMU, NRMV, ORTOL, SMAX,
1.4 bertrand 259: $ SMIN, SQRT2, THRESH, TOL, ULP,
1.1 bertrand 260: $ VLTGK, VUTGK, ZJTJI
261: * ..
262: * .. External Functions ..
263: LOGICAL LSAME
264: INTEGER IDAMAX
265: DOUBLE PRECISION DDOT, DLAMCH, DNRM2
266: EXTERNAL IDAMAX, LSAME, DAXPY, DDOT, DLAMCH, DNRM2
267: * ..
268: * .. External Subroutines ..
1.6 bertrand 269: EXTERNAL DSTEVX, DCOPY, DLASET, DSCAL, DSWAP, XERBLA
1.1 bertrand 270: * ..
271: * .. Intrinsic Functions ..
272: INTRINSIC ABS, DBLE, SIGN, SQRT
273: * ..
1.4 bertrand 274: * .. Executable Statements ..
1.1 bertrand 275: *
276: * Test the input parameters.
277: *
278: ALLSV = LSAME( RANGE, 'A' )
279: VALSV = LSAME( RANGE, 'V' )
280: INDSV = LSAME( RANGE, 'I' )
281: WANTZ = LSAME( JOBZ, 'V' )
282: LOWER = LSAME( UPLO, 'L' )
283: *
284: INFO = 0
285: IF( .NOT.LSAME( UPLO, 'U' ) .AND. .NOT.LOWER ) THEN
286: INFO = -1
287: ELSE IF( .NOT.( WANTZ .OR. LSAME( JOBZ, 'N' ) ) ) THEN
288: INFO = -2
289: ELSE IF( .NOT.( ALLSV .OR. VALSV .OR. INDSV ) ) THEN
290: INFO = -3
291: ELSE IF( N.LT.0 ) THEN
292: INFO = -4
293: ELSE IF( N.GT.0 ) THEN
294: IF( VALSV ) THEN
295: IF( VL.LT.ZERO ) THEN
296: INFO = -7
297: ELSE IF( VU.LE.VL ) THEN
298: INFO = -8
299: END IF
300: ELSE IF( INDSV ) THEN
301: IF( IL.LT.1 .OR. IL.GT.MAX( 1, N ) ) THEN
302: INFO = -9
303: ELSE IF( IU.LT.MIN( N, IL ) .OR. IU.GT.N ) THEN
304: INFO = -10
305: END IF
306: END IF
307: END IF
308: IF( INFO.EQ.0 ) THEN
309: IF( LDZ.LT.1 .OR. ( WANTZ .AND. LDZ.LT.N*2 ) ) INFO = -14
310: END IF
311: *
312: IF( INFO.NE.0 ) THEN
313: CALL XERBLA( 'DBDSVDX', -INFO )
314: RETURN
315: END IF
316: *
317: * Quick return if possible (N.LE.1)
318: *
319: NS = 0
320: IF( N.EQ.0 ) RETURN
1.4 bertrand 321: *
1.1 bertrand 322: IF( N.EQ.1 ) THEN
323: IF( ALLSV .OR. INDSV ) THEN
324: NS = 1
325: S( 1 ) = ABS( D( 1 ) )
326: ELSE
327: IF( VL.LT.ABS( D( 1 ) ) .AND. VU.GE.ABS( D( 1 ) ) ) THEN
328: NS = 1
329: S( 1 ) = ABS( D( 1 ) )
330: END IF
331: END IF
332: IF( WANTZ ) THEN
333: Z( 1, 1 ) = SIGN( ONE, D( 1 ) )
334: Z( 2, 1 ) = ONE
335: END IF
336: RETURN
337: END IF
338: *
1.4 bertrand 339: ABSTOL = 2*DLAMCH( 'Safe Minimum' )
1.1 bertrand 340: ULP = DLAMCH( 'Precision' )
341: EPS = DLAMCH( 'Epsilon' )
342: SQRT2 = SQRT( 2.0D0 )
343: ORTOL = SQRT( ULP )
1.4 bertrand 344: *
1.1 bertrand 345: * Criterion for splitting is taken from DBDSQR when singular
1.4 bertrand 346: * values are computed to relative accuracy TOL. (See J. Demmel and
347: * W. Kahan, Accurate singular values of bidiagonal matrices, SIAM
1.1 bertrand 348: * J. Sci. and Stat. Comput., 11:873–912, 1990.)
1.4 bertrand 349: *
1.1 bertrand 350: TOL = MAX( TEN, MIN( HNDRD, EPS**MEIGTH ) )*EPS
351: *
352: * Compute approximate maximum, minimum singular values.
353: *
354: I = IDAMAX( N, D, 1 )
355: SMAX = ABS( D( I ) )
356: I = IDAMAX( N-1, E, 1 )
357: SMAX = MAX( SMAX, ABS( E( I ) ) )
358: *
359: * Compute threshold for neglecting D's and E's.
360: *
361: SMIN = ABS( D( 1 ) )
362: IF( SMIN.NE.ZERO ) THEN
363: MU = SMIN
364: DO I = 2, N
365: MU = ABS( D( I ) )*( MU / ( MU+ABS( E( I-1 ) ) ) )
366: SMIN = MIN( SMIN, MU )
367: IF( SMIN.EQ.ZERO ) EXIT
368: END DO
369: END IF
370: SMIN = SMIN / SQRT( DBLE( N ) )
371: THRESH = TOL*SMIN
372: *
373: * Check for zeros in D and E (splits), i.e. submatrices.
374: *
375: DO I = 1, N-1
376: IF( ABS( D( I ) ).LE.THRESH ) D( I ) = ZERO
377: IF( ABS( E( I ) ).LE.THRESH ) E( I ) = ZERO
378: END DO
379: IF( ABS( D( N ) ).LE.THRESH ) D( N ) = ZERO
380: *
381: * Pointers for arrays used by DSTEVX.
382: *
383: IDTGK = 1
384: IETGK = IDTGK + N*2
385: ITEMP = IETGK + N*2
386: IIFAIL = 1
387: IIWORK = IIFAIL + N*2
388: *
389: * Set RNGVX, which corresponds to RANGE for DSTEVX in TGK mode.
1.4 bertrand 390: * VL,VU or IL,IU are redefined to conform to implementation a)
1.1 bertrand 391: * described in the leading comments.
392: *
393: ILTGK = 0
1.4 bertrand 394: IUTGK = 0
1.1 bertrand 395: VLTGK = ZERO
396: VUTGK = ZERO
397: *
398: IF( ALLSV ) THEN
399: *
1.4 bertrand 400: * All singular values will be found. We aim at -s (see
1.1 bertrand 401: * leading comments) with RNGVX = 'I'. IL and IU are set
1.4 bertrand 402: * later (as ILTGK and IUTGK) according to the dimension
1.1 bertrand 403: * of the active submatrix.
404: *
405: RNGVX = 'I'
1.2 bertrand 406: IF( WANTZ ) CALL DLASET( 'F', N*2, N+1, ZERO, ZERO, Z, LDZ )
1.1 bertrand 407: ELSE IF( VALSV ) THEN
408: *
409: * Find singular values in a half-open interval. We aim
410: * at -s (see leading comments) and we swap VL and VU
411: * (as VUTGK and VLTGK), changing their signs.
412: *
413: RNGVX = 'V'
414: VLTGK = -VU
415: VUTGK = -VL
416: WORK( IDTGK:IDTGK+2*N-1 ) = ZERO
417: CALL DCOPY( N, D, 1, WORK( IETGK ), 2 )
418: CALL DCOPY( N-1, E, 1, WORK( IETGK+1 ), 2 )
1.4 bertrand 419: CALL DSTEVX( 'N', 'V', N*2, WORK( IDTGK ), WORK( IETGK ),
1.1 bertrand 420: $ VLTGK, VUTGK, ILTGK, ILTGK, ABSTOL, NS, S,
421: $ Z, LDZ, WORK( ITEMP ), IWORK( IIWORK ),
422: $ IWORK( IIFAIL ), INFO )
423: IF( NS.EQ.0 ) THEN
424: RETURN
425: ELSE
1.2 bertrand 426: IF( WANTZ ) CALL DLASET( 'F', N*2, NS, ZERO, ZERO, Z, LDZ )
1.1 bertrand 427: END IF
428: ELSE IF( INDSV ) THEN
429: *
1.4 bertrand 430: * Find the IL-th through the IU-th singular values. We aim
431: * at -s (see leading comments) and indices are mapped into
1.1 bertrand 432: * values, therefore mimicking DSTEBZ, where
433: *
434: * GL = GL - FUDGE*TNORM*ULP*N - FUDGE*TWO*PIVMIN
435: * GU = GU + FUDGE*TNORM*ULP*N + FUDGE*PIVMIN
436: *
437: ILTGK = IL
1.4 bertrand 438: IUTGK = IU
1.1 bertrand 439: RNGVX = 'V'
440: WORK( IDTGK:IDTGK+2*N-1 ) = ZERO
441: CALL DCOPY( N, D, 1, WORK( IETGK ), 2 )
442: CALL DCOPY( N-1, E, 1, WORK( IETGK+1 ), 2 )
1.4 bertrand 443: CALL DSTEVX( 'N', 'I', N*2, WORK( IDTGK ), WORK( IETGK ),
1.1 bertrand 444: $ VLTGK, VLTGK, ILTGK, ILTGK, ABSTOL, NS, S,
445: $ Z, LDZ, WORK( ITEMP ), IWORK( IIWORK ),
446: $ IWORK( IIFAIL ), INFO )
447: VLTGK = S( 1 ) - FUDGE*SMAX*ULP*N
448: WORK( IDTGK:IDTGK+2*N-1 ) = ZERO
449: CALL DCOPY( N, D, 1, WORK( IETGK ), 2 )
450: CALL DCOPY( N-1, E, 1, WORK( IETGK+1 ), 2 )
1.4 bertrand 451: CALL DSTEVX( 'N', 'I', N*2, WORK( IDTGK ), WORK( IETGK ),
1.1 bertrand 452: $ VUTGK, VUTGK, IUTGK, IUTGK, ABSTOL, NS, S,
453: $ Z, LDZ, WORK( ITEMP ), IWORK( IIWORK ),
454: $ IWORK( IIFAIL ), INFO )
455: VUTGK = S( 1 ) + FUDGE*SMAX*ULP*N
456: VUTGK = MIN( VUTGK, ZERO )
457: *
458: * If VLTGK=VUTGK, DSTEVX returns an error message,
1.4 bertrand 459: * so if needed we change VUTGK slightly.
1.1 bertrand 460: *
461: IF( VLTGK.EQ.VUTGK ) VLTGK = VLTGK - TOL
462: *
1.2 bertrand 463: IF( WANTZ ) CALL DLASET( 'F', N*2, IU-IL+1, ZERO, ZERO, Z, LDZ)
1.4 bertrand 464: END IF
1.1 bertrand 465: *
466: * Initialize variables and pointers for S, Z, and WORK.
467: *
468: * NRU, NRV: number of rows in U and V for the active submatrix
469: * IDBEG, ISBEG: offsets for the entries of D and S
470: * IROWZ, ICOLZ: offsets for the rows and columns of Z
471: * IROWU, IROWV: offsets for the rows of U and V
472: *
473: NS = 0
474: NRU = 0
475: NRV = 0
476: IDBEG = 1
477: ISBEG = 1
478: IROWZ = 1
479: ICOLZ = 1
480: IROWU = 2
481: IROWV = 1
482: SPLIT = .FALSE.
1.4 bertrand 483: SVEQ0 = .FALSE.
1.1 bertrand 484: *
485: * Form the tridiagonal TGK matrix.
486: *
487: S( 1:N ) = ZERO
488: WORK( IETGK+2*N-1 ) = ZERO
489: WORK( IDTGK:IDTGK+2*N-1 ) = ZERO
490: CALL DCOPY( N, D, 1, WORK( IETGK ), 2 )
491: CALL DCOPY( N-1, E, 1, WORK( IETGK+1 ), 2 )
492: *
493: *
1.4 bertrand 494: * Check for splits in two levels, outer level
1.1 bertrand 495: * in E and inner level in D.
496: *
1.4 bertrand 497: DO IEPTR = 2, N*2, 2
498: IF( WORK( IETGK+IEPTR-1 ).EQ.ZERO ) THEN
1.1 bertrand 499: *
500: * Split in E (this piece of B is square) or bottom
501: * of the (input bidiagonal) matrix.
1.4 bertrand 502: *
1.1 bertrand 503: ISPLT = IDBEG
504: IDEND = IEPTR - 1
505: DO IDPTR = IDBEG, IDEND, 2
506: IF( WORK( IETGK+IDPTR-1 ).EQ.ZERO ) THEN
507: *
508: * Split in D (rectangular submatrix). Set the number
509: * of rows in U and V (NRU and NRV) accordingly.
510: *
511: IF( IDPTR.EQ.IDBEG ) THEN
512: *
513: * D=0 at the top.
514: *
515: SVEQ0 = .TRUE.
516: IF( IDBEG.EQ.IDEND) THEN
517: NRU = 1
518: NRV = 1
1.4 bertrand 519: END IF
1.1 bertrand 520: ELSE IF( IDPTR.EQ.IDEND ) THEN
521: *
522: * D=0 at the bottom.
523: *
524: SVEQ0 = .TRUE.
1.4 bertrand 525: NRU = (IDEND-ISPLT)/2 + 1
526: NRV = NRU
1.1 bertrand 527: IF( ISPLT.NE.IDBEG ) THEN
528: NRU = NRU + 1
1.4 bertrand 529: END IF
1.1 bertrand 530: ELSE
531: IF( ISPLT.EQ.IDBEG ) THEN
532: *
533: * Split: top rectangular submatrix.
1.4 bertrand 534: *
1.1 bertrand 535: NRU = (IDPTR-IDBEG)/2
536: NRV = NRU + 1
537: ELSE
538: *
539: * Split: middle square submatrix.
540: *
541: NRU = (IDPTR-ISPLT)/2 + 1
1.4 bertrand 542: NRV = NRU
1.1 bertrand 543: END IF
544: END IF
545: ELSE IF( IDPTR.EQ.IDEND ) THEN
546: *
547: * Last entry of D in the active submatrix.
548: *
549: IF( ISPLT.EQ.IDBEG ) THEN
550: *
551: * No split (trivial case).
552: *
553: NRU = (IDEND-IDBEG)/2 + 1
554: NRV = NRU
555: ELSE
556: *
557: * Split: bottom rectangular submatrix.
558: *
559: NRV = (IDEND-ISPLT)/2 + 1
1.4 bertrand 560: NRU = NRV + 1
1.1 bertrand 561: END IF
562: END IF
563: *
564: NTGK = NRU + NRV
565: *
566: IF( NTGK.GT.0 ) THEN
567: *
1.4 bertrand 568: * Compute eigenvalues/vectors of the active
569: * submatrix according to RANGE:
1.1 bertrand 570: * if RANGE='A' (ALLSV) then RNGVX = 'I'
571: * if RANGE='V' (VALSV) then RNGVX = 'V'
572: * if RANGE='I' (INDSV) then RNGVX = 'V'
573: *
574: ILTGK = 1
1.4 bertrand 575: IUTGK = NTGK / 2
1.1 bertrand 576: IF( ALLSV .OR. VUTGK.EQ.ZERO ) THEN
1.4 bertrand 577: IF( SVEQ0 .OR.
578: $ SMIN.LT.EPS .OR.
1.1 bertrand 579: $ MOD(NTGK,2).GT.0 ) THEN
580: * Special case: eigenvalue equal to zero or very
581: * small, additional eigenvector is needed.
582: IUTGK = IUTGK + 1
1.4 bertrand 583: END IF
1.1 bertrand 584: END IF
585: *
1.4 bertrand 586: * Workspace needed by DSTEVX:
587: * WORK( ITEMP: ): 2*5*NTGK
1.1 bertrand 588: * IWORK( 1: ): 2*6*NTGK
589: *
1.4 bertrand 590: CALL DSTEVX( JOBZ, RNGVX, NTGK, WORK( IDTGK+ISPLT-1 ),
591: $ WORK( IETGK+ISPLT-1 ), VLTGK, VUTGK,
592: $ ILTGK, IUTGK, ABSTOL, NSL, S( ISBEG ),
593: $ Z( IROWZ,ICOLZ ), LDZ, WORK( ITEMP ),
1.1 bertrand 594: $ IWORK( IIWORK ), IWORK( IIFAIL ),
595: $ INFO )
596: IF( INFO.NE.0 ) THEN
597: * Exit with the error code from DSTEVX.
598: RETURN
599: END IF
600: EMIN = ABS( MAXVAL( S( ISBEG:ISBEG+NSL-1 ) ) )
1.4 bertrand 601: *
1.1 bertrand 602: IF( NSL.GT.0 .AND. WANTZ ) THEN
603: *
604: * Normalize u=Z([2,4,...],:) and v=Z([1,3,...],:),
605: * changing the sign of v as discussed in the leading
606: * comments. The norms of u and v may be (slightly)
607: * different from 1/sqrt(2) if the corresponding
608: * eigenvalues are very small or too close. We check
609: * those norms and, if needed, reorthogonalize the
610: * vectors.
611: *
612: IF( NSL.GT.1 .AND.
613: $ VUTGK.EQ.ZERO .AND.
614: $ MOD(NTGK,2).EQ.0 .AND.
1.4 bertrand 615: $ EMIN.EQ.0 .AND. .NOT.SPLIT ) THEN
1.1 bertrand 616: *
617: * D=0 at the top or bottom of the active submatrix:
1.4 bertrand 618: * one eigenvalue is equal to zero; concatenate the
619: * eigenvectors corresponding to the two smallest
1.1 bertrand 620: * eigenvalues.
621: *
622: Z( IROWZ:IROWZ+NTGK-1,ICOLZ+NSL-2 ) =
623: $ Z( IROWZ:IROWZ+NTGK-1,ICOLZ+NSL-2 ) +
624: $ Z( IROWZ:IROWZ+NTGK-1,ICOLZ+NSL-1 )
1.4 bertrand 625: Z( IROWZ:IROWZ+NTGK-1,ICOLZ+NSL-1 ) =
626: $ ZERO
1.1 bertrand 627: * IF( IUTGK*2.GT.NTGK ) THEN
628: * Eigenvalue equal to zero or very small.
629: * NSL = NSL - 1
1.4 bertrand 630: * END IF
1.1 bertrand 631: END IF
632: *
633: DO I = 0, MIN( NSL-1, NRU-1 )
634: NRMU = DNRM2( NRU, Z( IROWU, ICOLZ+I ), 2 )
635: IF( NRMU.EQ.ZERO ) THEN
636: INFO = N*2 + 1
637: RETURN
638: END IF
1.4 bertrand 639: CALL DSCAL( NRU, ONE/NRMU,
1.1 bertrand 640: $ Z( IROWU,ICOLZ+I ), 2 )
641: IF( NRMU.NE.ONE .AND.
642: $ ABS( NRMU-ORTOL )*SQRT2.GT.ONE )
643: $ THEN
644: DO J = 0, I-1
1.4 bertrand 645: ZJTJI = -DDOT( NRU, Z( IROWU, ICOLZ+J ),
1.1 bertrand 646: $ 2, Z( IROWU, ICOLZ+I ), 2 )
1.4 bertrand 647: CALL DAXPY( NRU, ZJTJI,
1.1 bertrand 648: $ Z( IROWU, ICOLZ+J ), 2,
649: $ Z( IROWU, ICOLZ+I ), 2 )
650: END DO
651: NRMU = DNRM2( NRU, Z( IROWU, ICOLZ+I ), 2 )
1.4 bertrand 652: CALL DSCAL( NRU, ONE/NRMU,
1.1 bertrand 653: $ Z( IROWU,ICOLZ+I ), 2 )
654: END IF
655: END DO
656: DO I = 0, MIN( NSL-1, NRV-1 )
657: NRMV = DNRM2( NRV, Z( IROWV, ICOLZ+I ), 2 )
658: IF( NRMV.EQ.ZERO ) THEN
659: INFO = N*2 + 1
660: RETURN
661: END IF
1.4 bertrand 662: CALL DSCAL( NRV, -ONE/NRMV,
1.1 bertrand 663: $ Z( IROWV,ICOLZ+I ), 2 )
664: IF( NRMV.NE.ONE .AND.
665: $ ABS( NRMV-ORTOL )*SQRT2.GT.ONE )
666: $ THEN
667: DO J = 0, I-1
668: ZJTJI = -DDOT( NRV, Z( IROWV, ICOLZ+J ),
669: $ 2, Z( IROWV, ICOLZ+I ), 2 )
1.4 bertrand 670: CALL DAXPY( NRU, ZJTJI,
1.1 bertrand 671: $ Z( IROWV, ICOLZ+J ), 2,
672: $ Z( IROWV, ICOLZ+I ), 2 )
673: END DO
674: NRMV = DNRM2( NRV, Z( IROWV, ICOLZ+I ), 2 )
1.4 bertrand 675: CALL DSCAL( NRV, ONE/NRMV,
1.1 bertrand 676: $ Z( IROWV,ICOLZ+I ), 2 )
677: END IF
678: END DO
679: IF( VUTGK.EQ.ZERO .AND.
680: $ IDPTR.LT.IDEND .AND.
681: $ MOD(NTGK,2).GT.0 ) THEN
682: *
683: * D=0 in the middle of the active submatrix (one
1.4 bertrand 684: * eigenvalue is equal to zero): save the corresponding
1.1 bertrand 685: * eigenvector for later use (when bottom of the
686: * active submatrix is reached).
687: *
688: SPLIT = .TRUE.
1.4 bertrand 689: Z( IROWZ:IROWZ+NTGK-1,N+1 ) =
1.1 bertrand 690: $ Z( IROWZ:IROWZ+NTGK-1,NS+NSL )
1.4 bertrand 691: Z( IROWZ:IROWZ+NTGK-1,NS+NSL ) =
692: $ ZERO
693: END IF
1.1 bertrand 694: END IF !** WANTZ **!
1.4 bertrand 695: *
1.1 bertrand 696: NSL = MIN( NSL, NRU )
697: SVEQ0 = .FALSE.
698: *
699: * Absolute values of the eigenvalues of TGK.
700: *
701: DO I = 0, NSL-1
702: S( ISBEG+I ) = ABS( S( ISBEG+I ) )
703: END DO
704: *
705: * Update pointers for TGK, S and Z.
1.4 bertrand 706: *
1.1 bertrand 707: ISBEG = ISBEG + NSL
708: IROWZ = IROWZ + NTGK
709: ICOLZ = ICOLZ + NSL
710: IROWU = IROWZ
1.4 bertrand 711: IROWV = IROWZ + 1
1.1 bertrand 712: ISPLT = IDPTR + 1
713: NS = NS + NSL
714: NRU = 0
1.4 bertrand 715: NRV = 0
716: END IF !** NTGK.GT.0 **!
1.2 bertrand 717: IF( IROWZ.LT.N*2 .AND. WANTZ ) THEN
718: Z( 1:IROWZ-1, ICOLZ ) = ZERO
719: END IF
1.1 bertrand 720: END DO !** IDPTR loop **!
1.2 bertrand 721: IF( SPLIT .AND. WANTZ ) THEN
1.1 bertrand 722: *
723: * Bring back eigenvector corresponding
724: * to eigenvalue equal to zero.
725: *
1.4 bertrand 726: Z( IDBEG:IDEND-NTGK+1,ISBEG-1 ) =
1.1 bertrand 727: $ Z( IDBEG:IDEND-NTGK+1,ISBEG-1 ) +
728: $ Z( IDBEG:IDEND-NTGK+1,N+1 )
729: Z( IDBEG:IDEND-NTGK+1,N+1 ) = 0
730: END IF
731: IROWV = IROWV - 1
732: IROWU = IROWU + 1
733: IDBEG = IEPTR + 1
734: SVEQ0 = .FALSE.
1.4 bertrand 735: SPLIT = .FALSE.
1.1 bertrand 736: END IF !** Check for split in E **!
737: END DO !** IEPTR loop **!
738: *
739: * Sort the singular values into decreasing order (insertion sort on
740: * singular values, but only one transposition per singular vector)
741: *
742: DO I = 1, NS-1
743: K = 1
744: SMIN = S( 1 )
745: DO J = 2, NS + 1 - I
746: IF( S( J ).LE.SMIN ) THEN
747: K = J
748: SMIN = S( J )
749: END IF
750: END DO
751: IF( K.NE.NS+1-I ) THEN
752: S( K ) = S( NS+1-I )
753: S( NS+1-I ) = SMIN
1.2 bertrand 754: IF( WANTZ ) CALL DSWAP( N*2, Z( 1,K ), 1, Z( 1,NS+1-I ), 1 )
1.1 bertrand 755: END IF
756: END DO
1.4 bertrand 757: *
1.1 bertrand 758: * If RANGE=I, check for singular values/vectors to be discarded.
759: *
760: IF( INDSV ) THEN
761: K = IU - IL + 1
762: IF( K.LT.NS ) THEN
763: S( K+1:NS ) = ZERO
1.2 bertrand 764: IF( WANTZ ) Z( 1:N*2,K+1:NS ) = ZERO
1.1 bertrand 765: NS = K
766: END IF
1.4 bertrand 767: END IF
1.1 bertrand 768: *
769: * Reorder Z: U = Z( 1:N,1:NS ), V = Z( N+1:N*2,1:NS ).
770: * If B is a lower diagonal, swap U and V.
771: *
1.2 bertrand 772: IF( WANTZ ) THEN
1.1 bertrand 773: DO I = 1, NS
774: CALL DCOPY( N*2, Z( 1,I ), 1, WORK, 1 )
775: IF( LOWER ) THEN
776: CALL DCOPY( N, WORK( 2 ), 2, Z( N+1,I ), 1 )
777: CALL DCOPY( N, WORK( 1 ), 2, Z( 1 ,I ), 1 )
778: ELSE
779: CALL DCOPY( N, WORK( 2 ), 2, Z( 1 ,I ), 1 )
780: CALL DCOPY( N, WORK( 1 ), 2, Z( N+1,I ), 1 )
781: END IF
782: END DO
1.2 bertrand 783: END IF
1.1 bertrand 784: *
785: RETURN
786: *
787: * End of DBDSVDX
788: *
789: END
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