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OpenBLAS/lapack-netlib/SRC/clamswlq.f

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  1. *> \brief \b CLAMSWLQ

  2. *

  3. *  Definition:

  4. *  ===========

  5. *

  6. *      SUBROUTINE CLAMSWLQ( SIDE, TRANS, M, N, K, MB, NB, A, LDA, T,

  7. *     $                LDT, C, LDC, WORK, LWORK, INFO )

  8. *

  9. *

  10. *     .. Scalar Arguments ..

  11. *      CHARACTER         SIDE, TRANS

  12. *      INTEGER           INFO, LDA, M, N, K, MB, NB, LDT, LWORK, LDC

  13. *     ..

  14. *     .. Array Arguments ..

  15. *      COMPLEX        A( LDA, * ), WORK( * ), C(LDC, * ),

  16. *     $                  T( LDT, * )

  17. *> \par Purpose:

  18. *  =============

  19. *>

  20. *> \verbatim

  21. *>

  22. *>    CLAMSWLQ overwrites the general complex M-by-N matrix C with

  23. *>

  24. *>

  25. *>                    SIDE = 'L'     SIDE = 'R'

  26. *>    TRANS = 'N':      Q * C          C * Q

  27. *>    TRANS = 'T':      Q**H * C       C * Q**H

  28. *>    where Q is a complex unitary matrix defined as the product of blocked

  29. *>    elementary reflectors computed by short wide LQ

  30. *>    factorization (CLASWLQ)

  31. *> \endverbatim

  32. *

  33. *  Arguments:

  34. *  ==========

  35. *

  36. *> \param[in] SIDE

  37. *> \verbatim

  38. *>          SIDE is CHARACTER*1

  39. *>          = 'L': apply Q or Q**H from the Left;

  40. *>          = 'R': apply Q or Q**H from the Right.

  41. *> \endverbatim

  42. *>

  43. *> \param[in] TRANS

  44. *> \verbatim

  45. *>          TRANS is CHARACTER*1

  46. *>          = 'N':  No transpose, apply Q;

  47. *>          = 'C':  Conjugate transpose, apply Q**H.

  48. *> \endverbatim

  49. *>

  50. *> \param[in] M

  51. *> \verbatim

  52. *>          M is INTEGER

  53. *>          The number of rows of the matrix C.  M >=0.

  54. *> \endverbatim

  55. *>

  56. *> \param[in] N

  57. *> \verbatim

  58. *>          N is INTEGER

  59. *>          The number of columns of the matrix C. N >= 0.

  60. *> \endverbatim

  61. *>

  62. *> \param[in] K

  63. *> \verbatim

  64. *>          K is INTEGER

  65. *>          The number of elementary reflectors whose product defines

  66. *>          the matrix Q.

  67. *>          M >= K >= 0;

  68. *>

  69. *> \endverbatim

  70. *> \param[in] MB

  71. *> \verbatim

  72. *>          MB is INTEGER

  73. *>          The row block size to be used in the blocked LQ.

  74. *>          M >= MB >= 1

  75. *> \endverbatim

  76. *>

  77. *> \param[in] NB

  78. *> \verbatim

  79. *>          NB is INTEGER

  80. *>          The column block size to be used in the blocked LQ.

  81. *>          NB > M.

  82. *> \endverbatim

  83. *>

  84. *> \param[in] A

  85. *> \verbatim

  86. *>          A is COMPLEX array, dimension

  87. *>                               (LDA,M) if SIDE = 'L',

  88. *>                               (LDA,N) if SIDE = 'R'

  89. *>          The i-th row must contain the vector which defines the blocked

  90. *>          elementary reflector H(i), for i = 1,2,...,k, as returned by

  91. *>          CLASWLQ in the first k rows of its array argument A.

  92. *> \endverbatim

  93. *>

  94. *> \param[in] LDA

  95. *> \verbatim

  96. *>          LDA is INTEGER

  97. *>          The leading dimension of the array A. LDA => max(1,K).

  98. *> \endverbatim

  99. *>

  100. *> \param[in] T

  101. *> \verbatim

  102. *>          T is COMPLEX array, dimension

  103. *>          ( M * Number of blocks(CEIL(N-K/NB-K)),

  104. *>          The blocked upper triangular block reflectors stored in compact form

  105. *>          as a sequence of upper triangular blocks.  See below

  106. *>          for further details.

  107. *> \endverbatim

  108. *>

  109. *> \param[in] LDT

  110. *> \verbatim

  111. *>          LDT is INTEGER

  112. *>          The leading dimension of the array T.  LDT >= MB.

  113. *> \endverbatim

  114. *>

  115. *> \param[in,out] C

  116. *> \verbatim

  117. *>          C is COMPLEX array, dimension (LDC,N)

  118. *>          On entry, the M-by-N matrix C.

  119. *>          On exit, C is overwritten by Q*C or Q**H*C or C*Q**H or C*Q.

  120. *> \endverbatim

  121. *>

  122. *> \param[in] LDC

  123. *> \verbatim

  124. *>          LDC is INTEGER

  125. *>          The leading dimension of the array C. LDC >= max(1,M).

  126. *> \endverbatim

  127. *>

  128. *> \param[out] WORK

  129. *> \verbatim

  130. *>         (workspace) COMPLEX array, dimension (MAX(1,LWORK))

  131. *> \endverbatim

  132. *>

  133. *> \param[in] LWORK

  134. *> \verbatim

  135. *>          LWORK is INTEGER

  136. *>          The dimension of the array WORK.

  137. *>          If SIDE = 'L', LWORK >= max(1,NB) * MB;

  138. *>          if SIDE = 'R', LWORK >= max(1,M) * MB.

  139. *>          If LWORK = -1, then a workspace query is assumed; the routine

  140. *>          only calculates the optimal size of the WORK array, returns

  141. *>          this value as the first entry of the WORK array, and no error

  142. *>          message related to LWORK is issued by XERBLA.

  143. *> \endverbatim

  144. *>

  145. *> \param[out] INFO

  146. *> \verbatim

  147. *>          INFO is INTEGER

  148. *>          = 0:  successful exit

  149. *>          < 0:  if INFO = -i, the i-th argument had an illegal value

  150. *> \endverbatim

  151. *

  152. *  Authors:

  153. *  ========

  154. *

  155. *> \author Univ. of Tennessee

  156. *> \author Univ. of California Berkeley

  157. *> \author Univ. of Colorado Denver

  158. *> \author NAG Ltd.

  159. *

  160. *> \par Further Details:

  161. *  =====================

  162. *>

  163. *> \verbatim

  164. *> Short-Wide LQ (SWLQ) performs LQ by a sequence of unitary transformations,

  165. *> representing Q as a product of other unitary matrices

  166. *>   Q = Q(1) * Q(2) * . . . * Q(k)

  167. *> where each Q(i) zeros out upper diagonal entries of a block of NB rows of A:

  168. *>   Q(1) zeros out the upper diagonal entries of rows 1:NB of A

  169. *>   Q(2) zeros out the bottom MB-N rows of rows [1:M,NB+1:2*NB-M] of A

  170. *>   Q(3) zeros out the bottom MB-N rows of rows [1:M,2*NB-M+1:3*NB-2*M] of A

  171. *>   . . .

  172. *>

  173. *> Q(1) is computed by GELQT, which represents Q(1) by Householder vectors

  174. *> stored under the diagonal of rows 1:MB of A, and by upper triangular

  175. *> block reflectors, stored in array T(1:LDT,1:N).

  176. *> For more information see Further Details in GELQT.

  177. *>

  178. *> Q(i) for i>1 is computed by TPLQT, which represents Q(i) by Householder vectors

  179. *> stored in columns [(i-1)*(NB-M)+M+1:i*(NB-M)+M] of A, and by upper triangular

  180. *> block reflectors, stored in array T(1:LDT,(i-1)*M+1:i*M).

  181. *> The last Q(k) may use fewer rows.

  182. *> For more information see Further Details in TPLQT.

  183. *>

  184. *> For more details of the overall algorithm, see the description of

  185. *> Sequential TSQR in Section 2.2 of [1].

  186. *>

  187. *> [1] “Communication-Optimal Parallel and Sequential QR and LU Factorizations,”

  188. *>     J. Demmel, L. Grigori, M. Hoemmen, J. Langou,

  189. *>     SIAM J. Sci. Comput, vol. 34, no. 1, 2012

  190. *> \endverbatim

  191. *>

  192. *  =====================================================================

  193.       SUBROUTINE CLAMSWLQ( SIDE, TRANS, M, N, K, MB, NB, A, LDA, T,

  194.      $    LDT, C, LDC, WORK, LWORK, INFO )

  195. *

  196. *  -- LAPACK computational routine --

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

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

  199. *

  200. *     .. Scalar Arguments ..

  201.       CHARACTER         SIDE, TRANS

  202.       INTEGER           INFO, LDA, M, N, K, MB, NB, LDT, LWORK, LDC

  203. *     ..

  204. *     .. Array Arguments ..

  205.       COMPLEX           A( LDA, * ), WORK( * ), C(LDC, * ),

  206.      $      T( LDT, * )

  207. *     ..

  208. *

  209. * =====================================================================

  210. *

  211. *     ..

  212. *     .. Local Scalars ..

  213.       LOGICAL    LEFT, RIGHT, TRAN, NOTRAN, LQUERY

  214.       INTEGER    I, II, KK, LW, CTR

  215. *     ..

  216. *     .. External Functions ..

  217.       LOGICAL            LSAME

  218.       EXTERNAL           LSAME

  219. *     .. External Subroutines ..

  220.       EXTERNAL    CTPMLQT, CGEMLQT, XERBLA

  221. *     ..

  222. *     .. Executable Statements ..

  223. *

  224. *     Test the input arguments

  225. *

  226.       LQUERY  = LWORK.LT.0

  227.       NOTRAN  = LSAME( TRANS, 'N' )

  228.       TRAN    = LSAME( TRANS, 'C' )

  229.       LEFT    = LSAME( SIDE, 'L' )

  230.       RIGHT   = LSAME( SIDE, 'R' )

  231.       IF (LEFT) THEN

  232.         LW = N * MB

  233.       ELSE

  234.         LW = M * MB

  235.       END IF

  236. *

  237.       INFO = 0

  238.       IF( .NOT.LEFT .AND. .NOT.RIGHT ) THEN

  239.          INFO = -1

  240.       ELSE IF( .NOT.TRAN .AND. .NOT.NOTRAN ) THEN

  241.          INFO = -2

  242.       ELSE IF( K.LT.0 ) THEN

  243.         INFO = -5

  244.       ELSE IF( M.LT.K ) THEN

  245.         INFO = -3

  246.       ELSE IF( N.LT.0 ) THEN

  247.         INFO = -4

  248.       ELSE IF( K.LT.MB .OR. MB.LT.1) THEN

  249.         INFO = -6

  250.       ELSE IF( LDA.LT.MAX( 1, K ) ) THEN

  251.         INFO = -9

  252.       ELSE IF( LDT.LT.MAX( 1, MB) ) THEN

  253.         INFO = -11

  254.       ELSE IF( LDC.LT.MAX( 1, M ) ) THEN

  255.          INFO = -13

  256.       ELSE IF(( LWORK.LT.MAX(1,LW)).AND.(.NOT.LQUERY)) THEN

  257.         INFO = -15

  258.       END IF

  259. *

  260.       IF( INFO.NE.0 ) THEN

  261.         CALL XERBLA( 'CLAMSWLQ', -INFO )

  262.         WORK(1) = LW

  263.         RETURN

  264.       ELSE IF (LQUERY) THEN

  265.         WORK(1) = LW

  266.         RETURN

  267.       END IF

  268. *

  269. *     Quick return if possible

  270. *

  271.       IF( MIN(M,N,K).EQ.0 ) THEN

  272.         RETURN

  273.       END IF

  274. *

  275.       IF((NB.LE.K).OR.(NB.GE.MAX(M,N,K))) THEN

  276.         CALL CGEMLQT( SIDE, TRANS, M, N, K, MB, A, LDA,

  277.      $        T, LDT, C, LDC, WORK, INFO)

  278.         RETURN

  279.       END IF

  280. *

  281.       IF(LEFT.AND.TRAN) THEN

  282. *

  283. *         Multiply Q to the last block of C

  284. *

  285.           KK = MOD((M-K),(NB-K))

  286.           CTR = (M-K)/(NB-K)

  287.           IF (KK.GT.0) THEN

  288.             II=M-KK+1

  289.             CALL CTPMLQT('L','C',KK , N, K, 0, MB, A(1,II), LDA,

  290.      $        T(1,CTR*K+1), LDT, C(1,1), LDC,

  291.      $        C(II,1), LDC, WORK, INFO )

  292.           ELSE

  293.             II=M+1

  294.           END IF

  295. *

  296.           DO I=II-(NB-K),NB+1,-(NB-K)

  297. *

  298. *         Multiply Q to the current block of C (1:M,I:I+NB)

  299. *

  300.             CTR = CTR - 1

  301.             CALL CTPMLQT('L','C',NB-K , N, K, 0,MB, A(1,I), LDA,

  302.      $          T(1,CTR*K+1),LDT, C(1,1), LDC,

  303.      $          C(I,1), LDC, WORK, INFO )

  304. 

  305.           END DO

  306. *

  307. *         Multiply Q to the first block of C (1:M,1:NB)

  308. *

  309.           CALL CGEMLQT('L','C',NB , N, K, MB, A(1,1), LDA, T

  310.      $              ,LDT ,C(1,1), LDC, WORK, INFO )

  311. *

  312.       ELSE IF (LEFT.AND.NOTRAN) THEN

  313. *

  314. *         Multiply Q to the first block of C

  315. *

  316.          KK  = MOD((M-K),(NB-K))

  317.          II  = M-KK+1

  318.          CTR = 1

  319.          CALL CGEMLQT('L','N',NB , N, K, MB, A(1,1), LDA, T

  320.      $              ,LDT ,C(1,1), LDC, WORK, INFO )

  321. *

  322.          DO I=NB+1,II-NB+K,(NB-K)

  323. *

  324. *         Multiply Q to the current block of C (I:I+NB,1:N)

  325. *

  326.           CALL CTPMLQT('L','N',NB-K , N, K, 0,MB, A(1,I), LDA,

  327.      $         T(1, CTR *K+1), LDT, C(1,1), LDC,

  328.      $         C(I,1), LDC, WORK, INFO )

  329.           CTR = CTR + 1

  330. *

  331.          END DO

  332.          IF(II.LE.M) THEN

  333. *

  334. *         Multiply Q to the last block of C

  335. *

  336.           CALL CTPMLQT('L','N',KK , N, K, 0, MB, A(1,II), LDA,

  337.      $        T(1, CTR*K+1), LDT, C(1,1), LDC,

  338.      $        C(II,1), LDC, WORK, INFO )

  339. *

  340.          END IF

  341. *

  342.       ELSE IF(RIGHT.AND.NOTRAN) THEN

  343. *

  344. *         Multiply Q to the last block of C

  345. *

  346.           KK = MOD((N-K),(NB-K))

  347.           CTR = (N-K)/(NB-K)

  348.           IF (KK.GT.0) THEN

  349.             II=N-KK+1

  350.             CALL CTPMLQT('R','N',M , KK, K, 0, MB, A(1, II), LDA,

  351.      $        T(1,CTR*K+1), LDT, C(1,1), LDC,

  352.      $        C(1,II), LDC, WORK, INFO )

  353.           ELSE

  354.             II=N+1

  355.           END IF

  356. *

  357.           DO I=II-(NB-K),NB+1,-(NB-K)

  358. *

  359. *         Multiply Q to the current block of C (1:M,I:I+MB)

  360. *

  361.               CTR = CTR - 1

  362.               CALL CTPMLQT('R','N', M, NB-K, K, 0, MB, A(1, I), LDA,

  363.      $            T(1,CTR*K+1), LDT, C(1,1), LDC,

  364.      $            C(1,I), LDC, WORK, INFO )

  365.           END DO

  366. *

  367. *         Multiply Q to the first block of C (1:M,1:MB)

  368. *

  369.           CALL CGEMLQT('R','N',M , NB, K, MB, A(1,1), LDA, T

  370.      $            ,LDT ,C(1,1), LDC, WORK, INFO )

  371. *

  372.       ELSE IF (RIGHT.AND.TRAN) THEN

  373. *

  374. *       Multiply Q to the first block of C

  375. *

  376.          KK = MOD((N-K),(NB-K))

  377.          II=N-KK+1

  378.          CTR = 1

  379.          CALL CGEMLQT('R','C',M , NB, K, MB, A(1,1), LDA, T

  380.      $            ,LDT ,C(1,1), LDC, WORK, INFO )

  381. *

  382.          DO I=NB+1,II-NB+K,(NB-K)

  383. *

  384. *         Multiply Q to the current block of C (1:M,I:I+MB)

  385. *

  386.           CALL CTPMLQT('R','C',M , NB-K, K, 0,MB, A(1,I), LDA,

  387.      $       T(1,CTR*K+1), LDT, C(1,1), LDC,

  388.      $       C(1,I), LDC, WORK, INFO )

  389.           CTR = CTR + 1

  390. *

  391.          END DO

  392.          IF(II.LE.N) THEN

  393. *

  394. *       Multiply Q to the last block of C

  395. *

  396.           CALL CTPMLQT('R','C',M , KK, K, 0,MB, A(1,II), LDA,

  397.      $      T(1,CTR*K+1),LDT, C(1,1), LDC,

  398.      $      C(1,II), LDC, WORK, INFO )

  399. *

  400.          END IF

  401. *

  402.       END IF

  403. *

  404.       WORK(1) = LW

  405.       RETURN

  406. *

  407. *     End of CLAMSWLQ

  408. *

  409.       END