clarot.c
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00001 /* clarot.f -- translated by f2c (version 20061008).
00002    You must link the resulting object file with libf2c:
00003         on Microsoft Windows system, link with libf2c.lib;
00004         on Linux or Unix systems, link with .../path/to/libf2c.a -lm
00005         or, if you install libf2c.a in a standard place, with -lf2c -lm
00006         -- in that order, at the end of the command line, as in
00007                 cc *.o -lf2c -lm
00008         Source for libf2c is in /netlib/f2c/libf2c.zip, e.g.,
00009 
00010                 http://www.netlib.org/f2c/libf2c.zip
00011 */
00012 
00013 #include "f2c.h"
00014 #include "blaswrap.h"
00015 
00016 /* Table of constant values */
00017 
00018 static integer c__4 = 4;
00019 static integer c__8 = 8;
00020 
00021 /* Subroutine */ int clarot_(logical *lrows, logical *lleft, logical *lright, 
00022         integer *nl, complex *c__, complex *s, complex *a, integer *lda, 
00023         complex *xleft, complex *xright)
00024 {
00025     /* System generated locals */
00026     integer i__1, i__2, i__3, i__4;
00027     complex q__1, q__2, q__3, q__4, q__5, q__6;
00028 
00029     /* Builtin functions */
00030     void r_cnjg(complex *, complex *);
00031 
00032     /* Local variables */
00033     integer j, ix, iy, nt;
00034     complex xt[2], yt[2];
00035     integer iyt, iinc, inext;
00036     complex tempx;
00037     extern /* Subroutine */ int xerbla_(char *, integer *);
00038 
00039 
00040 /*  -- LAPACK auxiliary test routine (version 3.1) -- */
00041 /*     Univ. of Tennessee, Univ. of California Berkeley and NAG Ltd.. */
00042 /*     November 2006 */
00043 
00044 /*     .. Scalar Arguments .. */
00045 /*     .. */
00046 /*     .. Array Arguments .. */
00047 /*     .. */
00048 
00049 /*  Purpose */
00050 /*  ======= */
00051 
00052 /*     CLAROT applies a (Givens) rotation to two adjacent rows or */
00053 /*     columns, where one element of the first and/or last column/row */
00054 /*     for use on matrices stored in some format other than GE, so */
00055 /*     that elements of the matrix may be used or modified for which */
00056 /*     no array element is provided. */
00057 
00058 /*     One example is a symmetric matrix in SB format (bandwidth=4), for */
00059 /*     which UPLO='L':  Two adjacent rows will have the format: */
00060 
00061 /*     row j:     *  *  *  *  *  .  .  .  . */
00062 /*     row j+1:      *  *  *  *  *  .  .  .  . */
00063 
00064 /*     '*' indicates elements for which storage is provided, */
00065 /*     '.' indicates elements for which no storage is provided, but */
00066 /*     are not necessarily zero; their values are determined by */
00067 /*     symmetry.  ' ' indicates elements which are necessarily zero, */
00068 /*      and have no storage provided. */
00069 
00070 /*     Those columns which have two '*'s can be handled by SROT. */
00071 /*     Those columns which have no '*'s can be ignored, since as long */
00072 /*     as the Givens rotations are carefully applied to preserve */
00073 /*     symmetry, their values are determined. */
00074 /*     Those columns which have one '*' have to be handled separately, */
00075 /*     by using separate variables "p" and "q": */
00076 
00077 /*     row j:     *  *  *  *  *  p  .  .  . */
00078 /*     row j+1:   q  *  *  *  *  *  .  .  .  . */
00079 
00080 /*     The element p would have to be set correctly, then that column */
00081 /*     is rotated, setting p to its new value.  The next call to */
00082 /*     CLAROT would rotate columns j and j+1, using p, and restore */
00083 /*     symmetry.  The element q would start out being zero, and be */
00084 /*     made non-zero by the rotation.  Later, rotations would presumably */
00085 /*     be chosen to zero q out. */
00086 
00087 /*     Typical Calling Sequences: rotating the i-th and (i+1)-st rows. */
00088 /*     ------- ------- --------- */
00089 
00090 /*       General dense matrix: */
00091 
00092 /*               CALL CLAROT(.TRUE.,.FALSE.,.FALSE., N, C,S, */
00093 /*                       A(i,1),LDA, DUMMY, DUMMY) */
00094 
00095 /*       General banded matrix in GB format: */
00096 
00097 /*               j = MAX(1, i-KL ) */
00098 /*               NL = MIN( N, i+KU+1 ) + 1-j */
00099 /*               CALL CLAROT( .TRUE., i-KL.GE.1, i+KU.LT.N, NL, C,S, */
00100 /*                       A(KU+i+1-j,j),LDA-1, XLEFT, XRIGHT ) */
00101 
00102 /*               [ note that i+1-j is just MIN(i,KL+1) ] */
00103 
00104 /*       Symmetric banded matrix in SY format, bandwidth K, */
00105 /*       lower triangle only: */
00106 
00107 /*               j = MAX(1, i-K ) */
00108 /*               NL = MIN( K+1, i ) + 1 */
00109 /*               CALL CLAROT( .TRUE., i-K.GE.1, .TRUE., NL, C,S, */
00110 /*                       A(i,j), LDA, XLEFT, XRIGHT ) */
00111 
00112 /*       Same, but upper triangle only: */
00113 
00114 /*               NL = MIN( K+1, N-i ) + 1 */
00115 /*               CALL CLAROT( .TRUE., .TRUE., i+K.LT.N, NL, C,S, */
00116 /*                       A(i,i), LDA, XLEFT, XRIGHT ) */
00117 
00118 /*       Symmetric banded matrix in SB format, bandwidth K, */
00119 /*       lower triangle only: */
00120 
00121 /*               [ same as for SY, except:] */
00122 /*                   . . . . */
00123 /*                       A(i+1-j,j), LDA-1, XLEFT, XRIGHT ) */
00124 
00125 /*               [ note that i+1-j is just MIN(i,K+1) ] */
00126 
00127 /*       Same, but upper triangle only: */
00128 /*                   . . . */
00129 /*                       A(K+1,i), LDA-1, XLEFT, XRIGHT ) */
00130 
00131 /*       Rotating columns is just the transpose of rotating rows, except */
00132 /*       for GB and SB: (rotating columns i and i+1) */
00133 
00134 /*       GB: */
00135 /*               j = MAX(1, i-KU ) */
00136 /*               NL = MIN( N, i+KL+1 ) + 1-j */
00137 /*               CALL CLAROT( .TRUE., i-KU.GE.1, i+KL.LT.N, NL, C,S, */
00138 /*                       A(KU+j+1-i,i),LDA-1, XTOP, XBOTTM ) */
00139 
00140 /*               [note that KU+j+1-i is just MAX(1,KU+2-i)] */
00141 
00142 /*       SB: (upper triangle) */
00143 
00144 /*                    . . . . . . */
00145 /*                       A(K+j+1-i,i),LDA-1, XTOP, XBOTTM ) */
00146 
00147 /*       SB: (lower triangle) */
00148 
00149 /*                    . . . . . . */
00150 /*                       A(1,i),LDA-1, XTOP, XBOTTM ) */
00151 
00152 /*  Arguments */
00153 /*  ========= */
00154 
00155 /*  LROWS  - LOGICAL */
00156 /*           If .TRUE., then CLAROT will rotate two rows.  If .FALSE., */
00157 /*           then it will rotate two columns. */
00158 /*           Not modified. */
00159 
00160 /*  LLEFT  - LOGICAL */
00161 /*           If .TRUE., then XLEFT will be used instead of the */
00162 /*           corresponding element of A for the first element in the */
00163 /*           second row (if LROWS=.FALSE.) or column (if LROWS=.TRUE.) */
00164 /*           If .FALSE., then the corresponding element of A will be */
00165 /*           used. */
00166 /*           Not modified. */
00167 
00168 /*  LRIGHT - LOGICAL */
00169 /*           If .TRUE., then XRIGHT will be used instead of the */
00170 /*           corresponding element of A for the last element in the */
00171 /*           first row (if LROWS=.FALSE.) or column (if LROWS=.TRUE.) If */
00172 /*           .FALSE., then the corresponding element of A will be used. */
00173 /*           Not modified. */
00174 
00175 /*  NL     - INTEGER */
00176 /*           The length of the rows (if LROWS=.TRUE.) or columns (if */
00177 /*           LROWS=.FALSE.) to be rotated.  If XLEFT and/or XRIGHT are */
00178 /*           used, the columns/rows they are in should be included in */
00179 /*           NL, e.g., if LLEFT = LRIGHT = .TRUE., then NL must be at */
00180 /*           least 2.  The number of rows/columns to be rotated */
00181 /*           exclusive of those involving XLEFT and/or XRIGHT may */
00182 /*           not be negative, i.e., NL minus how many of LLEFT and */
00183 /*           LRIGHT are .TRUE. must be at least zero; if not, XERBLA */
00184 /*           will be called. */
00185 /*           Not modified. */
00186 
00187 /*  C, S   - COMPLEX */
00188 /*           Specify the Givens rotation to be applied.  If LROWS is */
00189 /*           true, then the matrix ( c  s ) */
00190 /*                                 ( _  _ ) */
00191 /*                                 (-s  c )  is applied from the left; */
00192 /*           if false, then the transpose (not conjugated) thereof is */
00193 /*           applied from the right.  Note that in contrast to the */
00194 /*           output of CROTG or to most versions of CROT, both C and S */
00195 /*           are complex.  For a Givens rotation, |C|**2 + |S|**2 should */
00196 /*           be 1, but this is not checked. */
00197 /*           Not modified. */
00198 
00199 /*  A      - COMPLEX array. */
00200 /*           The array containing the rows/columns to be rotated.  The */
00201 /*           first element of A should be the upper left element to */
00202 /*           be rotated. */
00203 /*           Read and modified. */
00204 
00205 /*  LDA    - INTEGER */
00206 /*           The "effective" leading dimension of A.  If A contains */
00207 /*           a matrix stored in GE, HE, or SY format, then this is just */
00208 /*           the leading dimension of A as dimensioned in the calling */
00209 /*           routine.  If A contains a matrix stored in band (GB, HB, or */
00210 /*           SB) format, then this should be *one less* than the leading */
00211 /*           dimension used in the calling routine.  Thus, if A were */
00212 /*           dimensioned A(LDA,*) in CLAROT, then A(1,j) would be the */
00213 /*           j-th element in the first of the two rows to be rotated, */
00214 /*           and A(2,j) would be the j-th in the second, regardless of */
00215 /*           how the array may be stored in the calling routine.  [A */
00216 /*           cannot, however, actually be dimensioned thus, since for */
00217 /*           band format, the row number may exceed LDA, which is not */
00218 /*           legal FORTRAN.] */
00219 /*           If LROWS=.TRUE., then LDA must be at least 1, otherwise */
00220 /*           it must be at least NL minus the number of .TRUE. values */
00221 /*           in XLEFT and XRIGHT. */
00222 /*           Not modified. */
00223 
00224 /*  XLEFT  - COMPLEX */
00225 /*           If LLEFT is .TRUE., then XLEFT will be used and modified */
00226 /*           instead of A(2,1) (if LROWS=.TRUE.) or A(1,2) */
00227 /*           (if LROWS=.FALSE.). */
00228 /*           Read and modified. */
00229 
00230 /*  XRIGHT - COMPLEX */
00231 /*           If LRIGHT is .TRUE., then XRIGHT will be used and modified */
00232 /*           instead of A(1,NL) (if LROWS=.TRUE.) or A(NL,1) */
00233 /*           (if LROWS=.FALSE.). */
00234 /*           Read and modified. */
00235 
00236 /*  ===================================================================== */
00237 
00238 /*     .. Local Scalars .. */
00239 /*     .. */
00240 /*     .. Local Arrays .. */
00241 /*     .. */
00242 /*     .. External Subroutines .. */
00243 /*     .. */
00244 /*     .. Intrinsic Functions .. */
00245 /*     .. */
00246 /*     .. Executable Statements .. */
00247 
00248 /*     Set up indices, arrays for ends */
00249 
00250     /* Parameter adjustments */
00251     --a;
00252 
00253     /* Function Body */
00254     if (*lrows) {
00255         iinc = *lda;
00256         inext = 1;
00257     } else {
00258         iinc = 1;
00259         inext = *lda;
00260     }
00261 
00262     if (*lleft) {
00263         nt = 1;
00264         ix = iinc + 1;
00265         iy = *lda + 2;
00266         xt[0].r = a[1].r, xt[0].i = a[1].i;
00267         yt[0].r = xleft->r, yt[0].i = xleft->i;
00268     } else {
00269         nt = 0;
00270         ix = 1;
00271         iy = inext + 1;
00272     }
00273 
00274     if (*lright) {
00275         iyt = inext + 1 + (*nl - 1) * iinc;
00276         ++nt;
00277         i__1 = nt - 1;
00278         xt[i__1].r = xright->r, xt[i__1].i = xright->i;
00279         i__1 = nt - 1;
00280         i__2 = iyt;
00281         yt[i__1].r = a[i__2].r, yt[i__1].i = a[i__2].i;
00282     }
00283 
00284 /*     Check for errors */
00285 
00286     if (*nl < nt) {
00287         xerbla_("CLAROT", &c__4);
00288         return 0;
00289     }
00290     if (*lda <= 0 || ! (*lrows) && *lda < *nl - nt) {
00291         xerbla_("CLAROT", &c__8);
00292         return 0;
00293     }
00294 
00295 /*     Rotate */
00296 
00297 /*     CROT( NL-NT, A(IX),IINC, A(IY),IINC, C, S ) with complex C, S */
00298 
00299     i__1 = *nl - nt - 1;
00300     for (j = 0; j <= i__1; ++j) {
00301         i__2 = ix + j * iinc;
00302         q__2.r = c__->r * a[i__2].r - c__->i * a[i__2].i, q__2.i = c__->r * a[
00303                 i__2].i + c__->i * a[i__2].r;
00304         i__3 = iy + j * iinc;
00305         q__3.r = s->r * a[i__3].r - s->i * a[i__3].i, q__3.i = s->r * a[i__3]
00306                 .i + s->i * a[i__3].r;
00307         q__1.r = q__2.r + q__3.r, q__1.i = q__2.i + q__3.i;
00308         tempx.r = q__1.r, tempx.i = q__1.i;
00309         i__2 = iy + j * iinc;
00310         r_cnjg(&q__4, s);
00311         q__3.r = -q__4.r, q__3.i = -q__4.i;
00312         i__3 = ix + j * iinc;
00313         q__2.r = q__3.r * a[i__3].r - q__3.i * a[i__3].i, q__2.i = q__3.r * a[
00314                 i__3].i + q__3.i * a[i__3].r;
00315         r_cnjg(&q__6, c__);
00316         i__4 = iy + j * iinc;
00317         q__5.r = q__6.r * a[i__4].r - q__6.i * a[i__4].i, q__5.i = q__6.r * a[
00318                 i__4].i + q__6.i * a[i__4].r;
00319         q__1.r = q__2.r + q__5.r, q__1.i = q__2.i + q__5.i;
00320         a[i__2].r = q__1.r, a[i__2].i = q__1.i;
00321         i__2 = ix + j * iinc;
00322         a[i__2].r = tempx.r, a[i__2].i = tempx.i;
00323 /* L10: */
00324     }
00325 
00326 /*     CROT( NT, XT,1, YT,1, C, S ) with complex C, S */
00327 
00328     i__1 = nt;
00329     for (j = 1; j <= i__1; ++j) {
00330         i__2 = j - 1;
00331         q__2.r = c__->r * xt[i__2].r - c__->i * xt[i__2].i, q__2.i = c__->r * 
00332                 xt[i__2].i + c__->i * xt[i__2].r;
00333         i__3 = j - 1;
00334         q__3.r = s->r * yt[i__3].r - s->i * yt[i__3].i, q__3.i = s->r * yt[
00335                 i__3].i + s->i * yt[i__3].r;
00336         q__1.r = q__2.r + q__3.r, q__1.i = q__2.i + q__3.i;
00337         tempx.r = q__1.r, tempx.i = q__1.i;
00338         i__2 = j - 1;
00339         r_cnjg(&q__4, s);
00340         q__3.r = -q__4.r, q__3.i = -q__4.i;
00341         i__3 = j - 1;
00342         q__2.r = q__3.r * xt[i__3].r - q__3.i * xt[i__3].i, q__2.i = q__3.r * 
00343                 xt[i__3].i + q__3.i * xt[i__3].r;
00344         r_cnjg(&q__6, c__);
00345         i__4 = j - 1;
00346         q__5.r = q__6.r * yt[i__4].r - q__6.i * yt[i__4].i, q__5.i = q__6.r * 
00347                 yt[i__4].i + q__6.i * yt[i__4].r;
00348         q__1.r = q__2.r + q__5.r, q__1.i = q__2.i + q__5.i;
00349         yt[i__2].r = q__1.r, yt[i__2].i = q__1.i;
00350         i__2 = j - 1;
00351         xt[i__2].r = tempx.r, xt[i__2].i = tempx.i;
00352 /* L20: */
00353     }
00354 
00355 /*     Stuff values back into XLEFT, XRIGHT, etc. */
00356 
00357     if (*lleft) {
00358         a[1].r = xt[0].r, a[1].i = xt[0].i;
00359         xleft->r = yt[0].r, xleft->i = yt[0].i;
00360     }
00361 
00362     if (*lright) {
00363         i__1 = nt - 1;
00364         xright->r = xt[i__1].r, xright->i = xt[i__1].i;
00365         i__1 = iyt;
00366         i__2 = nt - 1;
00367         a[i__1].r = yt[i__2].r, a[i__1].i = yt[i__2].i;
00368     }
00369 
00370     return 0;
00371 
00372 /*     End of CLAROT */
00373 
00374 } /* clarot_ */


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autogenerated on Sat Jun 8 2019 18:55:31