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OpenBLAS/lapack-netlib/TESTING/MATGEN/slarot.f

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  1. *> \brief \b SLAROT

  2. *

  3. *  =========== DOCUMENTATION ===========

  4. *

  5. * Online html documentation available at

  6. *            http://www.netlib.org/lapack/explore-html/

  7. *

  8. *  Definition:

  9. *  ===========

  10. *

  11. *       SUBROUTINE SLAROT( LROWS, LLEFT, LRIGHT, NL, C, S, A, LDA, XLEFT,

  12. *                          XRIGHT )

  13. *

  14. *       .. Scalar Arguments ..

  15. *       LOGICAL            LLEFT, LRIGHT, LROWS

  16. *       INTEGER            LDA, NL

  17. *       REAL               C, S, XLEFT, XRIGHT

  18. *       ..

  19. *       .. Array Arguments ..

  20. *       REAL               A( * )

  21. *       ..

  22. *

  23. *

  24. *> \par Purpose:

  25. *  =============

  26. *>

  27. *> \verbatim

  28. *>

  29. *>    SLAROT applies a (Givens) rotation to two adjacent rows or

  30. *>    columns, where one element of the first and/or last column/row

  31. *>    for use on matrices stored in some format other than GE, so

  32. *>    that elements of the matrix may be used or modified for which

  33. *>    no array element is provided.

  34. *>

  35. *>    One example is a symmetric matrix in SB format (bandwidth=4), for

  36. *>    which UPLO='L':  Two adjacent rows will have the format:

  37. *>

  38. *>    row j:     C> C> C> C> C> .  .  .  .

  39. *>    row j+1:      C> C> C> C> C> .  .  .  .

  40. *>

  41. *>    '*' indicates elements for which storage is provided,

  42. *>    '.' indicates elements for which no storage is provided, but

  43. *>    are not necessarily zero; their values are determined by

  44. *>    symmetry.  ' ' indicates elements which are necessarily zero,

  45. *>     and have no storage provided.

  46. *>

  47. *>    Those columns which have two '*'s can be handled by SROT.

  48. *>    Those columns which have no '*'s can be ignored, since as long

  49. *>    as the Givens rotations are carefully applied to preserve

  50. *>    symmetry, their values are determined.

  51. *>    Those columns which have one '*' have to be handled separately,

  52. *>    by using separate variables "p" and "q":

  53. *>

  54. *>    row j:     C> C> C> C> C> p  .  .  .

  55. *>    row j+1:   q  C> C> C> C> C> .  .  .  .

  56. *>

  57. *>    The element p would have to be set correctly, then that column

  58. *>    is rotated, setting p to its new value.  The next call to

  59. *>    SLAROT would rotate columns j and j+1, using p, and restore

  60. *>    symmetry.  The element q would start out being zero, and be

  61. *>    made non-zero by the rotation.  Later, rotations would presumably

  62. *>    be chosen to zero q out.

  63. *>

  64. *>    Typical Calling Sequences: rotating the i-th and (i+1)-st rows.

  65. *>    ------- ------- ---------

  66. *>

  67. *>      General dense matrix:

  68. *>

  69. *>              CALL SLAROT(.TRUE.,.FALSE.,.FALSE., N, C,S,

  70. *>                      A(i,1),LDA, DUMMY, DUMMY)

  71. *>

  72. *>      General banded matrix in GB format:

  73. *>

  74. *>              j = MAX(1, i-KL )

  75. *>              NL = MIN( N, i+KU+1 ) + 1-j

  76. *>              CALL SLAROT( .TRUE., i-KL.GE.1, i+KU.LT.N, NL, C,S,

  77. *>                      A(KU+i+1-j,j),LDA-1, XLEFT, XRIGHT )

  78. *>

  79. *>              [ note that i+1-j is just MIN(i,KL+1) ]

  80. *>

  81. *>      Symmetric banded matrix in SY format, bandwidth K,

  82. *>      lower triangle only:

  83. *>

  84. *>              j = MAX(1, i-K )

  85. *>              NL = MIN( K+1, i ) + 1

  86. *>              CALL SLAROT( .TRUE., i-K.GE.1, .TRUE., NL, C,S,

  87. *>                      A(i,j), LDA, XLEFT, XRIGHT )

  88. *>

  89. *>      Same, but upper triangle only:

  90. *>

  91. *>              NL = MIN( K+1, N-i ) + 1

  92. *>              CALL SLAROT( .TRUE., .TRUE., i+K.LT.N, NL, C,S,

  93. *>                      A(i,i), LDA, XLEFT, XRIGHT )

  94. *>

  95. *>      Symmetric banded matrix in SB format, bandwidth K,

  96. *>      lower triangle only:

  97. *>

  98. *>              [ same as for SY, except:]

  99. *>                  . . . .

  100. *>                      A(i+1-j,j), LDA-1, XLEFT, XRIGHT )

  101. *>

  102. *>              [ note that i+1-j is just MIN(i,K+1) ]

  103. *>

  104. *>      Same, but upper triangle only:

  105. *>                   . . .

  106. *>                      A(K+1,i), LDA-1, XLEFT, XRIGHT )

  107. *>

  108. *>      Rotating columns is just the transpose of rotating rows, except

  109. *>      for GB and SB: (rotating columns i and i+1)

  110. *>

  111. *>      GB:

  112. *>              j = MAX(1, i-KU )

  113. *>              NL = MIN( N, i+KL+1 ) + 1-j

  114. *>              CALL SLAROT( .TRUE., i-KU.GE.1, i+KL.LT.N, NL, C,S,

  115. *>                      A(KU+j+1-i,i),LDA-1, XTOP, XBOTTM )

  116. *>

  117. *>              [note that KU+j+1-i is just MAX(1,KU+2-i)]

  118. *>

  119. *>      SB: (upper triangle)

  120. *>

  121. *>                   . . . . . .

  122. *>                      A(K+j+1-i,i),LDA-1, XTOP, XBOTTM )

  123. *>

  124. *>      SB: (lower triangle)

  125. *>

  126. *>                   . . . . . .

  127. *>                      A(1,i),LDA-1, XTOP, XBOTTM )

  128. *> \endverbatim

  129. *

  130. *  Arguments:

  131. *  ==========

  132. *

  133. *> \verbatim

  134. *>  LROWS  - LOGICAL

  135. *>           If .TRUE., then SLAROT will rotate two rows.  If .FALSE.,

  136. *>           then it will rotate two columns.

  137. *>           Not modified.

  138. *>

  139. *>  LLEFT  - LOGICAL

  140. *>           If .TRUE., then XLEFT will be used instead of the

  141. *>           corresponding element of A for the first element in the

  142. *>           second row (if LROWS=.FALSE.) or column (if LROWS=.TRUE.)

  143. *>           If .FALSE., then the corresponding element of A will be

  144. *>           used.

  145. *>           Not modified.

  146. *>

  147. *>  LRIGHT - LOGICAL

  148. *>           If .TRUE., then XRIGHT will be used instead of the

  149. *>           corresponding element of A for the last element in the

  150. *>           first row (if LROWS=.FALSE.) or column (if LROWS=.TRUE.) If

  151. *>           .FALSE., then the corresponding element of A will be used.

  152. *>           Not modified.

  153. *>

  154. *>  NL     - INTEGER

  155. *>           The length of the rows (if LROWS=.TRUE.) or columns (if

  156. *>           LROWS=.FALSE.) to be rotated.  If XLEFT and/or XRIGHT are

  157. *>           used, the columns/rows they are in should be included in

  158. *>           NL, e.g., if LLEFT = LRIGHT = .TRUE., then NL must be at

  159. *>           least 2.  The number of rows/columns to be rotated

  160. *>           exclusive of those involving XLEFT and/or XRIGHT may

  161. *>           not be negative, i.e., NL minus how many of LLEFT and

  162. *>           LRIGHT are .TRUE. must be at least zero; if not, XERBLA

  163. *>           will be called.

  164. *>           Not modified.

  165. *>

  166. *>  C, S   - REAL

  167. *>           Specify the Givens rotation to be applied.  If LROWS is

  168. *>           true, then the matrix ( c  s )

  169. *>                                 (-s  c )  is applied from the left;

  170. *>           if false, then the transpose thereof is applied from the

  171. *>           right.  For a Givens rotation, C**2 + S**2 should be 1,

  172. *>           but this is not checked.

  173. *>           Not modified.

  174. *>

  175. *>  A      - REAL array.

  176. *>           The array containing the rows/columns to be rotated.  The

  177. *>           first element of A should be the upper left element to

  178. *>           be rotated.

  179. *>           Read and modified.

  180. *>

  181. *>  LDA    - INTEGER

  182. *>           The "effective" leading dimension of A.  If A contains

  183. *>           a matrix stored in GE or SY format, then this is just

  184. *>           the leading dimension of A as dimensioned in the calling

  185. *>           routine.  If A contains a matrix stored in band (GB or SB)

  186. *>           format, then this should be *one less* than the leading

  187. *>           dimension used in the calling routine.  Thus, if

  188. *>           A were dimensioned A(LDA,*) in SLAROT, then A(1,j) would

  189. *>           be the j-th element in the first of the two rows

  190. *>           to be rotated, and A(2,j) would be the j-th in the second,

  191. *>           regardless of how the array may be stored in the calling

  192. *>           routine.  [A cannot, however, actually be dimensioned thus,

  193. *>           since for band format, the row number may exceed LDA, which

  194. *>           is not legal FORTRAN.]

  195. *>           If LROWS=.TRUE., then LDA must be at least 1, otherwise

  196. *>           it must be at least NL minus the number of .TRUE. values

  197. *>           in XLEFT and XRIGHT.

  198. *>           Not modified.

  199. *>

  200. *>  XLEFT  - REAL

  201. *>           If LLEFT is .TRUE., then XLEFT will be used and modified

  202. *>           instead of A(2,1) (if LROWS=.TRUE.) or A(1,2)

  203. *>           (if LROWS=.FALSE.).

  204. *>           Read and modified.

  205. *>

  206. *>  XRIGHT - REAL

  207. *>           If LRIGHT is .TRUE., then XRIGHT will be used and modified

  208. *>           instead of A(1,NL) (if LROWS=.TRUE.) or A(NL,1)

  209. *>           (if LROWS=.FALSE.).

  210. *>           Read and modified.

  211. *> \endverbatim

  212. *

  213. *  Authors:

  214. *  ========

  215. *

  216. *> \author Univ. of Tennessee

  217. *> \author Univ. of California Berkeley

  218. *> \author Univ. of Colorado Denver

  219. *> \author NAG Ltd.

  220. *

  221. *> \ingroup real_matgen

  222. *

  223. *  =====================================================================

  224.       SUBROUTINE SLAROT( LROWS, LLEFT, LRIGHT, NL, C, S, A, LDA, XLEFT,

  225.      $                   XRIGHT )

  226. *

  227. *  -- LAPACK auxiliary routine --

  228. *  -- LAPACK is a software package provided by Univ. of Tennessee,    --

  229. *  -- Univ. of California Berkeley, Univ. of Colorado Denver and NAG Ltd..--

  230. *

  231. *     .. Scalar Arguments ..

  232.       LOGICAL            LLEFT, LRIGHT, LROWS

  233.       INTEGER            LDA, NL

  234.       REAL               C, S, XLEFT, XRIGHT

  235. *     ..

  236. *     .. Array Arguments ..

  237.       REAL               A( * )

  238. *     ..

  239. *

  240. *  =====================================================================

  241. *

  242. *     .. Local Scalars ..

  243.       INTEGER            IINC, INEXT, IX, IY, IYT, NT

  244. *     ..

  245. *     .. Local Arrays ..

  246.       REAL               XT( 2 ), YT( 2 )

  247. *     ..

  248. *     .. External Subroutines ..

  249.       EXTERNAL           SROT, XERBLA

  250. *     ..

  251. *     .. Executable Statements ..

  252. *

  253. *     Set up indices, arrays for ends

  254. *

  255.       IF( LROWS ) THEN

  256.          IINC = LDA

  257.          INEXT = 1

  258.       ELSE

  259.          IINC = 1

  260.          INEXT = LDA

  261.       END IF

  262. *

  263.       IF( LLEFT ) THEN

  264.          NT = 1

  265.          IX = 1 + IINC

  266.          IY = 2 + LDA

  267.          XT( 1 ) = A( 1 )

  268.          YT( 1 ) = XLEFT

  269.       ELSE

  270.          NT = 0

  271.          IX = 1

  272.          IY = 1 + INEXT

  273.       END IF

  274. *

  275.       IF( LRIGHT ) THEN

  276.          IYT = 1 + INEXT + ( NL-1 )*IINC

  277.          NT = NT + 1

  278.          XT( NT ) = XRIGHT

  279.          YT( NT ) = A( IYT )

  280.       END IF

  281. *

  282. *     Check for errors

  283. *

  284.       IF( NL.LT.NT ) THEN

  285.          CALL XERBLA( 'SLAROT', 4 )

  286.          RETURN

  287.       END IF

  288.       IF( LDA.LE.0 .OR. ( .NOT.LROWS .AND. LDA.LT.NL-NT ) ) THEN

  289.          CALL XERBLA( 'SLAROT', 8 )

  290.          RETURN

  291.       END IF

  292. *

  293. *     Rotate

  294. *

  295.       CALL SROT( NL-NT, A( IX ), IINC, A( IY ), IINC, C, S )

  296.       CALL SROT( NT, XT, 1, YT, 1, C, S )

  297. *

  298. *     Stuff values back into XLEFT, XRIGHT, etc.

  299. *

  300.       IF( LLEFT ) THEN

  301.          A( 1 ) = XT( 1 )

  302.          XLEFT = YT( 1 )

  303.       END IF

  304. *

  305.       IF( LRIGHT ) THEN

  306.          XRIGHT = XT( NT )

  307.          A( IYT ) = YT( NT )

  308.       END IF

  309. *

  310.       RETURN

  311. *

  312. *     End of SLAROT

  313. *

  314.       END