1 | *> \brief \b ZLARFT
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2 | *
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3 | * =========== DOCUMENTATION ===========
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4 | *
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5 | * Online html documentation available at
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6 | * http://www.netlib.org/lapack/explore-html/
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7 | *
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8 | *> \htmlonly
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9 | *> Download ZLARFT + dependencies
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10 | *> <a href="http://www.netlib.org/cgi-bin/netlibfiles.tgz?format=tgz&filename=/lapack/lapack_routine/zlarft.f">
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11 | *> [TGZ]</a>
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12 | *> <a href="http://www.netlib.org/cgi-bin/netlibfiles.zip?format=zip&filename=/lapack/lapack_routine/zlarft.f">
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13 | *> [ZIP]</a>
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14 | *> <a href="http://www.netlib.org/cgi-bin/netlibfiles.txt?format=txt&filename=/lapack/lapack_routine/zlarft.f">
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15 | *> [TXT]</a>
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16 | *> \endhtmlonly
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17 | *
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18 | * Definition:
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19 | * ===========
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20 | *
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21 | * SUBROUTINE ZLARFT( DIRECT, STOREV, N, K, V, LDV, TAU, T, LDT )
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22 | *
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23 | * .. Scalar Arguments ..
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24 | * CHARACTER DIRECT, STOREV
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25 | * INTEGER K, LDT, LDV, N
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26 | * ..
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27 | * .. Array Arguments ..
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28 | * COMPLEX*16 T( LDT, * ), TAU( * ), V( LDV, * )
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29 | * ..
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30 | *
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31 | *
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32 | *> \par Purpose:
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33 | * =============
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34 | *>
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35 | *> \verbatim
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36 | *>
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37 | *> ZLARFT forms the triangular factor T of a complex block reflector H
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38 | *> of order n, which is defined as a product of k elementary reflectors.
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39 | *>
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40 | *> If DIRECT = 'F', H = H(1) H(2) . . . H(k) and T is upper triangular;
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41 | *>
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42 | *> If DIRECT = 'B', H = H(k) . . . H(2) H(1) and T is lower triangular.
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43 | *>
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44 | *> If STOREV = 'C', the vector which defines the elementary reflector
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45 | *> H(i) is stored in the i-th column of the array V, and
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46 | *>
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47 | *> H = I - V * T * V**H
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48 | *>
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49 | *> If STOREV = 'R', the vector which defines the elementary reflector
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50 | *> H(i) is stored in the i-th row of the array V, and
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51 | *>
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52 | *> H = I - V**H * T * V
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53 | *> \endverbatim
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54 | *
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55 | * Arguments:
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56 | * ==========
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57 | *
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58 | *> \param[in] DIRECT
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59 | *> \verbatim
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60 | *> DIRECT is CHARACTER*1
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61 | *> Specifies the order in which the elementary reflectors are
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62 | *> multiplied to form the block reflector:
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63 | *> = 'F': H = H(1) H(2) . . . H(k) (Forward)
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64 | *> = 'B': H = H(k) . . . H(2) H(1) (Backward)
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65 | *> \endverbatim
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66 | *>
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67 | *> \param[in] STOREV
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68 | *> \verbatim
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69 | *> STOREV is CHARACTER*1
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70 | *> Specifies how the vectors which define the elementary
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71 | *> reflectors are stored (see also Further Details):
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72 | *> = 'C': columnwise
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73 | *> = 'R': rowwise
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74 | *> \endverbatim
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75 | *>
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76 | *> \param[in] N
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77 | *> \verbatim
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78 | *> N is INTEGER
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79 | *> The order of the block reflector H. N >= 0.
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80 | *> \endverbatim
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81 | *>
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82 | *> \param[in] K
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83 | *> \verbatim
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84 | *> K is INTEGER
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85 | *> The order of the triangular factor T (= the number of
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86 | *> elementary reflectors). K >= 1.
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87 | *> \endverbatim
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88 | *>
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89 | *> \param[in] V
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90 | *> \verbatim
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91 | *> V is COMPLEX*16 array, dimension
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92 | *> (LDV,K) if STOREV = 'C'
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93 | *> (LDV,N) if STOREV = 'R'
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94 | *> The matrix V. See further details.
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95 | *> \endverbatim
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96 | *>
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97 | *> \param[in] LDV
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98 | *> \verbatim
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99 | *> LDV is INTEGER
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100 | *> The leading dimension of the array V.
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101 | *> If STOREV = 'C', LDV >= max(1,N); if STOREV = 'R', LDV >= K.
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102 | *> \endverbatim
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103 | *>
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104 | *> \param[in] TAU
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105 | *> \verbatim
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106 | *> TAU is COMPLEX*16 array, dimension (K)
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107 | *> TAU(i) must contain the scalar factor of the elementary
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108 | *> reflector H(i).
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109 | *> \endverbatim
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110 | *>
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111 | *> \param[out] T
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112 | *> \verbatim
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113 | *> T is COMPLEX*16 array, dimension (LDT,K)
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114 | *> The k by k triangular factor T of the block reflector.
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115 | *> If DIRECT = 'F', T is upper triangular; if DIRECT = 'B', T is
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116 | *> lower triangular. The rest of the array is not used.
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117 | *> \endverbatim
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118 | *>
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119 | *> \param[in] LDT
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120 | *> \verbatim
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121 | *> LDT is INTEGER
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122 | *> The leading dimension of the array T. LDT >= K.
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123 | *> \endverbatim
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124 | *
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125 | * Authors:
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126 | * ========
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127 | *
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128 | *> \author Univ. of Tennessee
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129 | *> \author Univ. of California Berkeley
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130 | *> \author Univ. of Colorado Denver
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131 | *> \author NAG Ltd.
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132 | *
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133 | *> \date April 2012
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134 | *
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135 | *> \ingroup complex16OTHERauxiliary
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136 | *
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137 | *> \par Further Details:
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138 | * =====================
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139 | *>
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140 | *> \verbatim
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141 | *>
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142 | *> The shape of the matrix V and the storage of the vectors which define
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143 | *> the H(i) is best illustrated by the following example with n = 5 and
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144 | *> k = 3. The elements equal to 1 are not stored.
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145 | *>
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146 | *> DIRECT = 'F' and STOREV = 'C': DIRECT = 'F' and STOREV = 'R':
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147 | *>
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148 | *> V = ( 1 ) V = ( 1 v1 v1 v1 v1 )
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149 | *> ( v1 1 ) ( 1 v2 v2 v2 )
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150 | *> ( v1 v2 1 ) ( 1 v3 v3 )
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151 | *> ( v1 v2 v3 )
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152 | *> ( v1 v2 v3 )
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153 | *>
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154 | *> DIRECT = 'B' and STOREV = 'C': DIRECT = 'B' and STOREV = 'R':
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155 | *>
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156 | *> V = ( v1 v2 v3 ) V = ( v1 v1 1 )
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157 | *> ( v1 v2 v3 ) ( v2 v2 v2 1 )
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158 | *> ( 1 v2 v3 ) ( v3 v3 v3 v3 1 )
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159 | *> ( 1 v3 )
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160 | *> ( 1 )
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161 | *> \endverbatim
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162 | *>
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163 | * =====================================================================
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164 | SUBROUTINE ZLARFT( DIRECT, STOREV, N, K, V, LDV, TAU, T, LDT )
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165 | *
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166 | * -- LAPACK auxiliary routine (version 3.4.1) --
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167 | * -- LAPACK is a software package provided by Univ. of Tennessee, --
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168 | * -- Univ. of California Berkeley, Univ. of Colorado Denver and NAG Ltd..--
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169 | * April 2012
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170 | *
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171 | * .. Scalar Arguments ..
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172 | CHARACTER DIRECT, STOREV
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173 | INTEGER K, LDT, LDV, N
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174 | * ..
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175 | * .. Array Arguments ..
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176 | COMPLEX*16 T( LDT, * ), TAU( * ), V( LDV, * )
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177 | * ..
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178 | *
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179 | * =====================================================================
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180 | *
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181 | * .. Parameters ..
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182 | COMPLEX*16 ONE, ZERO
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183 | PARAMETER ( ONE = ( 1.0D+0, 0.0D+0 ),
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184 | $ ZERO = ( 0.0D+0, 0.0D+0 ) )
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185 | * ..
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186 | * .. Local Scalars ..
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187 | INTEGER I, J, PREVLASTV, LASTV
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188 | * ..
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189 | * .. External Subroutines ..
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190 | EXTERNAL ZGEMV, ZLACGV, ZTRMV
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191 | * ..
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192 | * .. External Functions ..
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193 | LOGICAL LSAME
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194 | EXTERNAL LSAME
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195 | * ..
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196 | * .. Executable Statements ..
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197 | *
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198 | * Quick return if possible
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199 | *
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200 | IF( N.EQ.0 )
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201 | $ RETURN
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202 | *
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203 | IF( LSAME( DIRECT, 'F' ) ) THEN
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204 | PREVLASTV = N
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205 | DO I = 1, K
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206 | PREVLASTV = MAX( PREVLASTV, I )
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207 | IF( TAU( I ).EQ.ZERO ) THEN
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208 | *
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209 | * H(i) = I
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210 | *
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211 | DO J = 1, I
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212 | T( J, I ) = ZERO
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213 | END DO
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214 | ELSE
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215 | *
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216 | * general case
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217 | *
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218 | IF( LSAME( STOREV, 'C' ) ) THEN
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219 | * Skip any trailing zeros.
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220 | DO LASTV = N, I+1, -1
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221 | IF( V( LASTV, I ).NE.ZERO ) EXIT
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222 | END DO
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223 | DO J = 1, I-1
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224 | T( J, I ) = -TAU( I ) * CONJG( V( I , J ) )
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225 | END DO
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226 | J = MIN( LASTV, PREVLASTV )
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227 | *
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228 | * T(1:i-1,i) := - tau(i) * V(i:j,1:i-1)**H * V(i:j,i)
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229 | *
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230 | CALL ZGEMV( 'Conjugate transpose', J-I, I-1,
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231 | $ -TAU( I ), V( I+1, 1 ), LDV,
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232 | $ V( I+1, I ), 1, ONE, T( 1, I ), 1 )
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233 | ELSE
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234 | * Skip any trailing zeros.
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235 | DO LASTV = N, I+1, -1
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236 | IF( V( I, LASTV ).NE.ZERO ) EXIT
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237 | END DO
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238 | DO J = 1, I-1
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239 | T( J, I ) = -TAU( I ) * V( J , I )
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240 | END DO
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241 | J = MIN( LASTV, PREVLASTV )
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242 | *
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243 | * T(1:i-1,i) := - tau(i) * V(1:i-1,i:j) * V(i,i:j)**H
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244 | *
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245 | CALL ZGEMM( 'N', 'C', I-1, 1, J-I, -TAU( I ),
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246 | $ V( 1, I+1 ), LDV, V( I, I+1 ), LDV,
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247 | $ ONE, T( 1, I ), LDT )
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248 | END IF
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249 | *
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250 | * T(1:i-1,i) := T(1:i-1,1:i-1) * T(1:i-1,i)
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251 | *
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252 | CALL ZTRMV( 'Upper', 'No transpose', 'Non-unit', I-1, T,
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253 | $ LDT, T( 1, I ), 1 )
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254 | T( I, I ) = TAU( I )
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255 | IF( I.GT.1 ) THEN
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256 | PREVLASTV = MAX( PREVLASTV, LASTV )
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257 | ELSE
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258 | PREVLASTV = LASTV
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259 | END IF
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260 | END IF
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261 | END DO
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262 | ELSE
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263 | PREVLASTV = 1
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264 | DO I = K, 1, -1
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265 | IF( TAU( I ).EQ.ZERO ) THEN
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266 | *
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267 | * H(i) = I
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268 | *
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269 | DO J = I, K
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270 | T( J, I ) = ZERO
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271 | END DO
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272 | ELSE
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273 | *
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274 | * general case
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275 | *
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276 | IF( I.LT.K ) THEN
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277 | IF( LSAME( STOREV, 'C' ) ) THEN
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278 | * Skip any leading zeros.
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279 | DO LASTV = 1, I-1
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280 | IF( V( LASTV, I ).NE.ZERO ) EXIT
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281 | END DO
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282 | DO J = I+1, K
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283 | T( J, I ) = -TAU( I ) * CONJG( V( N-K+I , J ) )
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284 | END DO
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285 | J = MAX( LASTV, PREVLASTV )
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286 | *
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287 | * T(i+1:k,i) = -tau(i) * V(j:n-k+i,i+1:k)**H * V(j:n-k+i,i)
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288 | *
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289 | CALL ZGEMV( 'Conjugate transpose', N-K+I-J, K-I,
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290 | $ -TAU( I ), V( J, I+1 ), LDV, V( J, I ),
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291 | $ 1, ONE, T( I+1, I ), 1 )
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292 | ELSE
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293 | * Skip any leading zeros.
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294 | DO LASTV = 1, I-1
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295 | IF( V( I, LASTV ).NE.ZERO ) EXIT
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296 | END DO
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297 | DO J = I+1, K
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298 | T( J, I ) = -TAU( I ) * V( J, N-K+I )
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299 | END DO
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300 | J = MAX( LASTV, PREVLASTV )
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301 | *
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302 | * T(i+1:k,i) = -tau(i) * V(i+1:k,j:n-k+i) * V(i,j:n-k+i)**H
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303 | *
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304 | CALL ZGEMM( 'N', 'C', K-I, 1, N-K+I-J, -TAU( I ),
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305 | $ V( I+1, J ), LDV, V( I, J ), LDV,
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306 | $ ONE, T( I+1, I ), LDT )
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307 | END IF
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308 | *
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309 | * T(i+1:k,i) := T(i+1:k,i+1:k) * T(i+1:k,i)
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310 | *
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311 | CALL ZTRMV( 'Lower', 'No transpose', 'Non-unit', K-I,
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312 | $ T( I+1, I+1 ), LDT, T( I+1, I ), 1 )
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313 | IF( I.GT.1 ) THEN
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314 | PREVLASTV = MIN( PREVLASTV, LASTV )
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315 | ELSE
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316 | PREVLASTV = LASTV
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317 | END IF
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318 | END IF
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319 | T( I, I ) = TAU( I )
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320 | END IF
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321 | END DO
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322 | END IF
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323 | RETURN
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324 | *
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325 | * End of ZLARFT
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326 | *
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327 | END
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