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OpenBLAS/lapack-netlib/SRC/claic1.f

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  1. *> \brief \b CLAIC1 applies one step of incremental condition estimation.

  2. *

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

  4. *

  5. * Online html documentation available at

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

  7. *

  8. *> \htmlonly

  9. *> Download CLAIC1 + dependencies

  10. *> <a href="http://www.netlib.org/cgi-bin/netlibfiles.tgz?format=tgz&filename=/lapack/lapack_routine/claic1.f">

  11. *> [TGZ]</a>

  12. *> <a href="http://www.netlib.org/cgi-bin/netlibfiles.zip?format=zip&filename=/lapack/lapack_routine/claic1.f">

  13. *> [ZIP]</a>

  14. *> <a href="http://www.netlib.org/cgi-bin/netlibfiles.txt?format=txt&filename=/lapack/lapack_routine/claic1.f">

  15. *> [TXT]</a>

  16. *> \endhtmlonly

  17. *

  18. *  Definition:

  19. *  ===========

  20. *

  21. *       SUBROUTINE CLAIC1( JOB, J, X, SEST, W, GAMMA, SESTPR, S, C )

  22. *

  23. *       .. Scalar Arguments ..

  24. *       INTEGER            J, JOB

  25. *       REAL               SEST, SESTPR

  26. *       COMPLEX            C, GAMMA, S

  27. *       ..

  28. *       .. Array Arguments ..

  29. *       COMPLEX            W( J ), X( J )

  30. *       ..

  31. *

  32. *

  33. *> \par Purpose:

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

  35. *>

  36. *> \verbatim

  37. *>

  38. *> CLAIC1 applies one step of incremental condition estimation in

  39. *> its simplest version:

  40. *>

  41. *> Let x, twonorm(x) = 1, be an approximate singular vector of an j-by-j

  42. *> lower triangular matrix L, such that

  43. *>          twonorm(L*x) = sest

  44. *> Then CLAIC1 computes sestpr, s, c such that

  45. *> the vector

  46. *>                 [ s*x ]

  47. *>          xhat = [  c  ]

  48. *> is an approximate singular vector of

  49. *>                 [ L      0  ]

  50. *>          Lhat = [ w**H gamma ]

  51. *> in the sense that

  52. *>          twonorm(Lhat*xhat) = sestpr.

  53. *>

  54. *> Depending on JOB, an estimate for the largest or smallest singular

  55. *> value is computed.

  56. *>

  57. *> Note that [s c]**H and sestpr**2 is an eigenpair of the system

  58. *>

  59. *>     diag(sest*sest, 0) + [alpha  gamma] * [ conjg(alpha) ]

  60. *>                                           [ conjg(gamma) ]

  61. *>

  62. *> where  alpha =  x**H*w.

  63. *> \endverbatim

  64. *

  65. *  Arguments:

  66. *  ==========

  67. *

  68. *> \param[in] JOB

  69. *> \verbatim

  70. *>          JOB is INTEGER

  71. *>          = 1: an estimate for the largest singular value is computed.

  72. *>          = 2: an estimate for the smallest singular value is computed.

  73. *> \endverbatim

  74. *>

  75. *> \param[in] J

  76. *> \verbatim

  77. *>          J is INTEGER

  78. *>          Length of X and W

  79. *> \endverbatim

  80. *>

  81. *> \param[in] X

  82. *> \verbatim

  83. *>          X is COMPLEX array, dimension (J)

  84. *>          The j-vector x.

  85. *> \endverbatim

  86. *>

  87. *> \param[in] SEST

  88. *> \verbatim

  89. *>          SEST is REAL

  90. *>          Estimated singular value of j by j matrix L

  91. *> \endverbatim

  92. *>

  93. *> \param[in] W

  94. *> \verbatim

  95. *>          W is COMPLEX array, dimension (J)

  96. *>          The j-vector w.

  97. *> \endverbatim

  98. *>

  99. *> \param[in] GAMMA

  100. *> \verbatim

  101. *>          GAMMA is COMPLEX

  102. *>          The diagonal element gamma.

  103. *> \endverbatim

  104. *>

  105. *> \param[out] SESTPR

  106. *> \verbatim

  107. *>          SESTPR is REAL

  108. *>          Estimated singular value of (j+1) by (j+1) matrix Lhat.

  109. *> \endverbatim

  110. *>

  111. *> \param[out] S

  112. *> \verbatim

  113. *>          S is COMPLEX

  114. *>          Sine needed in forming xhat.

  115. *> \endverbatim

  116. *>

  117. *> \param[out] C

  118. *> \verbatim

  119. *>          C is COMPLEX

  120. *>          Cosine needed in forming xhat.

  121. *> \endverbatim

  122. *

  123. *  Authors:

  124. *  ========

  125. *

  126. *> \author Univ. of Tennessee

  127. *> \author Univ. of California Berkeley

  128. *> \author Univ. of Colorado Denver

  129. *> \author NAG Ltd.

  130. *

  131. *> \ingroup complexOTHERauxiliary

  132. *

  133. *  =====================================================================

  134.       SUBROUTINE CLAIC1( JOB, J, X, SEST, W, GAMMA, SESTPR, S, C )

  135. *

  136. *  -- LAPACK auxiliary routine --

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

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

  139. *

  140. *     .. Scalar Arguments ..

  141.       INTEGER            J, JOB

  142.       REAL               SEST, SESTPR

  143.       COMPLEX            C, GAMMA, S

  144. *     ..

  145. *     .. Array Arguments ..

  146.       COMPLEX            W( J ), X( J )

  147. *     ..

  148. *

  149. *  =====================================================================

  150. *

  151. *     .. Parameters ..

  152.       REAL               ZERO, ONE, TWO

  153.       PARAMETER          ( ZERO = 0.0E0, ONE = 1.0E0, TWO = 2.0E0 )

  154.       REAL               HALF, FOUR

  155.       PARAMETER          ( HALF = 0.5E0, FOUR = 4.0E0 )

  156. *     ..

  157. *     .. Local Scalars ..

  158.       REAL               ABSALP, ABSEST, ABSGAM, B, EPS, NORMA, S1, S2,

  159.      $                   SCL, T, TEST, TMP, ZETA1, ZETA2

  160.       COMPLEX            ALPHA, COSINE, SINE

  161. *     ..

  162. *     .. Intrinsic Functions ..

  163.       INTRINSIC          ABS, CONJG, MAX, SQRT

  164. *     ..

  165. *     .. External Functions ..

  166.       REAL               SLAMCH

  167.       COMPLEX            CDOTC

  168.       EXTERNAL           SLAMCH, CDOTC

  169. *     ..

  170. *     .. Executable Statements ..

  171. *

  172.       EPS = SLAMCH( 'Epsilon' )

  173.       ALPHA = CDOTC( J, X, 1, W, 1 )

  174. *

  175.       ABSALP = ABS( ALPHA )

  176.       ABSGAM = ABS( GAMMA )

  177.       ABSEST = ABS( SEST )

  178. *

  179.       IF( JOB.EQ.1 ) THEN

  180. *

  181. *        Estimating largest singular value

  182. *

  183. *        special cases

  184. *

  185.          IF( SEST.EQ.ZERO ) THEN

  186.             S1 = MAX( ABSGAM, ABSALP )

  187.             IF( S1.EQ.ZERO ) THEN

  188.                S = ZERO

  189.                C = ONE

  190.                SESTPR = ZERO

  191.             ELSE

  192.                S = ALPHA / S1

  193.                C = GAMMA / S1

  194.                TMP = REAL( SQRT( S*CONJG( S )+C*CONJG( C ) ) )

  195.                S = S / TMP

  196.                C = C / TMP

  197.                SESTPR = S1*TMP

  198.             END IF

  199.             RETURN

  200.          ELSE IF( ABSGAM.LE.EPS*ABSEST ) THEN

  201.             S = ONE

  202.             C = ZERO

  203.             TMP = MAX( ABSEST, ABSALP )

  204.             S1 = ABSEST / TMP

  205.             S2 = ABSALP / TMP

  206.             SESTPR = TMP*SQRT( S1*S1+S2*S2 )

  207.             RETURN

  208.          ELSE IF( ABSALP.LE.EPS*ABSEST ) THEN

  209.             S1 = ABSGAM

  210.             S2 = ABSEST

  211.             IF( S1.LE.S2 ) THEN

  212.                S = ONE

  213.                C = ZERO

  214.                SESTPR = S2

  215.             ELSE

  216.                S = ZERO

  217.                C = ONE

  218.                SESTPR = S1

  219.             END IF

  220.             RETURN

  221.          ELSE IF( ABSEST.LE.EPS*ABSALP .OR. ABSEST.LE.EPS*ABSGAM ) THEN

  222.             S1 = ABSGAM

  223.             S2 = ABSALP

  224.             IF( S1.LE.S2 ) THEN

  225.                TMP = S1 / S2

  226.                SCL = SQRT( ONE+TMP*TMP )

  227.                SESTPR = S2*SCL

  228.                S = ( ALPHA / S2 ) / SCL

  229.                C = ( GAMMA / S2 ) / SCL

  230.             ELSE

  231.                TMP = S2 / S1

  232.                SCL = SQRT( ONE+TMP*TMP )

  233.                SESTPR = S1*SCL

  234.                S = ( ALPHA / S1 ) / SCL

  235.                C = ( GAMMA / S1 ) / SCL

  236.             END IF

  237.             RETURN

  238.          ELSE

  239. *

  240. *           normal case

  241. *

  242.             ZETA1 = ABSALP / ABSEST

  243.             ZETA2 = ABSGAM / ABSEST

  244. *

  245.             B = ( ONE-ZETA1*ZETA1-ZETA2*ZETA2 )*HALF

  246.             C = ZETA1*ZETA1

  247.             IF( B.GT.ZERO ) THEN

  248.                T = REAL( C / ( B+SQRT( B*B+C ) ) )

  249.             ELSE

  250.                T = REAL( SQRT( B*B+C ) - B )

  251.             END IF

  252. *

  253.             SINE = -( ALPHA / ABSEST ) / T

  254.             COSINE = -( GAMMA / ABSEST ) / ( ONE+T )

  255.             TMP = REAL( SQRT( SINE * CONJG( SINE )

  256.      $        + COSINE * CONJG( COSINE ) ) )

  257.             S = SINE / TMP

  258.             C = COSINE / TMP

  259.             SESTPR = SQRT( T+ONE )*ABSEST

  260.             RETURN

  261.          END IF

  262. *

  263.       ELSE IF( JOB.EQ.2 ) THEN

  264. *

  265. *        Estimating smallest singular value

  266. *

  267. *        special cases

  268. *

  269.          IF( SEST.EQ.ZERO ) THEN

  270.             SESTPR = ZERO

  271.             IF( MAX( ABSGAM, ABSALP ).EQ.ZERO ) THEN

  272.                SINE = ONE

  273.                COSINE = ZERO

  274.             ELSE

  275.                SINE = -CONJG( GAMMA )

  276.                COSINE = CONJG( ALPHA )

  277.             END IF

  278.             S1 = MAX( ABS( SINE ), ABS( COSINE ) )

  279.             S = SINE / S1

  280.             C = COSINE / S1

  281.             TMP = REAL( SQRT( S*CONJG( S )+C*CONJG( C ) ) )

  282.             S = S / TMP

  283.             C = C / TMP

  284.             RETURN

  285.          ELSE IF( ABSGAM.LE.EPS*ABSEST ) THEN

  286.             S = ZERO

  287.             C = ONE

  288.             SESTPR = ABSGAM

  289.             RETURN

  290.          ELSE IF( ABSALP.LE.EPS*ABSEST ) THEN

  291.             S1 = ABSGAM

  292.             S2 = ABSEST

  293.             IF( S1.LE.S2 ) THEN

  294.                S = ZERO

  295.                C = ONE

  296.                SESTPR = S1

  297.             ELSE

  298.                S = ONE

  299.                C = ZERO

  300.                SESTPR = S2

  301.             END IF

  302.             RETURN

  303.          ELSE IF( ABSEST.LE.EPS*ABSALP .OR. ABSEST.LE.EPS*ABSGAM ) THEN

  304.             S1 = ABSGAM

  305.             S2 = ABSALP

  306.             IF( S1.LE.S2 ) THEN

  307.                TMP = S1 / S2

  308.                SCL = SQRT( ONE+TMP*TMP )

  309.                SESTPR = ABSEST*( TMP / SCL )

  310.                S = -( CONJG( GAMMA ) / S2 ) / SCL

  311.                C = ( CONJG( ALPHA ) / S2 ) / SCL

  312.             ELSE

  313.                TMP = S2 / S1

  314.                SCL = SQRT( ONE+TMP*TMP )

  315.                SESTPR = ABSEST / SCL

  316.                S = -( CONJG( GAMMA ) / S1 ) / SCL

  317.                C = ( CONJG( ALPHA ) / S1 ) / SCL

  318.             END IF

  319.             RETURN

  320.          ELSE

  321. *

  322. *           normal case

  323. *

  324.             ZETA1 = ABSALP / ABSEST

  325.             ZETA2 = ABSGAM / ABSEST

  326. *

  327.             NORMA = MAX( ONE+ZETA1*ZETA1+ZETA1*ZETA2,

  328.      $              ZETA1*ZETA2+ZETA2*ZETA2 )

  329. *

  330. *           See if root is closer to zero or to ONE

  331. *

  332.             TEST = ONE + TWO*( ZETA1-ZETA2 )*( ZETA1+ZETA2 )

  333.             IF( TEST.GE.ZERO ) THEN

  334. *

  335. *              root is close to zero, compute directly

  336. *

  337.                B = ( ZETA1*ZETA1+ZETA2*ZETA2+ONE )*HALF

  338.                C = ZETA2*ZETA2

  339.                T = REAL( C / ( B+SQRT( ABS( B*B-C ) ) ) )

  340.                SINE = ( ALPHA / ABSEST ) / ( ONE-T )

  341.                COSINE = -( GAMMA / ABSEST ) / T

  342.                SESTPR = SQRT( T+FOUR*EPS*EPS*NORMA )*ABSEST

  343.             ELSE

  344. *

  345. *              root is closer to ONE, shift by that amount

  346. *

  347.                B = ( ZETA2*ZETA2+ZETA1*ZETA1-ONE )*HALF

  348.                C = ZETA1*ZETA1

  349.                IF( B.GE.ZERO ) THEN

  350.                   T = REAL( -C / ( B+SQRT( B*B+C ) ) )

  351.                ELSE

  352.                   T = REAL( B - SQRT( B*B+C ) )

  353.                END IF

  354.                SINE = -( ALPHA / ABSEST ) / T

  355.                COSINE = -( GAMMA / ABSEST ) / ( ONE+T )

  356.                SESTPR = SQRT( ONE+T+FOUR*EPS*EPS*NORMA )*ABSEST

  357.             END IF

  358.             TMP = REAL( SQRT( SINE * CONJG( SINE )

  359.      $        + COSINE * CONJG( COSINE ) ) )

  360.             S = SINE / TMP

  361.             C = COSINE / TMP

  362.             RETURN

  363. *

  364.          END IF

  365.       END IF

  366.       RETURN

  367. *

  368. *     End of CLAIC1

  369. *

  370.       END