1 *> \brief \b SLASYF_AASEN
3 * =========== DOCUMENTATION ===========
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21 * SUBROUTINE SLASYF_AASEN( UPLO, J1, M, NB, A, LDA, IPIV,
22 * H, LDH, WORK, INFO )
24 * .. Scalar Arguments ..
26 * INTEGER J1, M, NB, LDA, LDH, INFO
28 * .. Array Arguments ..
30 * REAL A( LDA, * ), H( LDH, * ), WORK( * )
39 *> DLATRF_AASEN factorizes a panel of a real symmetric matrix A using
40 *> the Aasen's algorithm. The panel consists of a set of NB rows of A
41 *> when UPLO is U, or a set of NB columns when UPLO is L.
43 *> In order to factorize the panel, the Aasen's algorithm requires the
44 *> last row, or column, of the previous panel. The first row, or column,
45 *> of A is set to be the first row, or column, of an identity matrix,
46 *> which is used to factorize the first panel.
48 *> The resulting J-th row of U, or J-th column of L, is stored in the
49 *> (J-1)-th row, or column, of A (without the unit diatonals), while
50 *> the diagonal and subdiagonal of A are overwritten by those of T.
59 *> UPLO is CHARACTER*1
60 *> = 'U': Upper triangle of A is stored;
61 *> = 'L': Lower triangle of A is stored.
67 *> The location of the first row, or column, of the panel
68 *> within the submatrix of A, passed to this routine, e.g.,
69 *> when called by SSYTRF_AASEN, for the first panel, J1 is 1,
70 *> while for the remaining panels, J1 is 2.
76 *> The dimension of the submatrix. M >= 0.
82 *> The dimension of the panel to be facotorized.
87 *> A is REAL array, dimension (LDA,M) for
88 *> the first panel, while dimension (LDA,M+1) for the
91 *> On entry, A contains the last row, or column, of
92 *> the previous panel, and the trailing submatrix of A
93 *> to be factorized, except for the first panel, only
94 *> the panel is passed.
96 *> On exit, the leading panel is factorized.
102 *> The leading dimension of the array A. LDA >= max(1,N).
107 *> IPIV is INTEGER array, dimension (N)
108 *> Details of the row and column interchanges,
109 *> the row and column k were interchanged with the row and
115 *> H is REAL workspace, dimension (LDH,NB).
122 *> The leading dimension of the workspace H. LDH >= max(1,M).
127 *> WORK is REAL workspace, dimension (M).
133 *> = 0: successful exit
134 *> < 0: if INFO = -i, the i-th argument had an illegal value
135 *> > 0: if INFO = i, D(i,i) is exactly zero. The factorization
136 *> has been completed, but the block diagonal matrix D is
137 *> exactly singular, and division by zero will occur if it
138 *> is used to solve a system of equations.
144 *> \author Univ. of Tennessee
145 *> \author Univ. of California Berkeley
146 *> \author Univ. of Colorado Denver
149 *> \date November 2016
151 *> \ingroup realSYcomputational
153 * @generated from dlasyf_aasen.f, fortran d -> s, Sun Oct 2 22:57:56 2016
155 * =====================================================================
156 SUBROUTINE SLASYF_AASEN( UPLO, J1, M, NB, A, LDA, IPIV,
157 $ H, LDH, WORK, INFO )
159 * -- LAPACK computational routine (version 3.4.0) --
160 * -- LAPACK is a software package provided by Univ. of Tennessee, --
161 * -- Univ. of California Berkeley, Univ. of Colorado Denver and NAG Ltd..--
166 * .. Scalar Arguments ..
168 INTEGER M, NB, J1, LDA, LDH, INFO
170 * .. Array Arguments ..
172 REAL A( LDA, * ), H( LDH, * ), WORK( * )
175 * =====================================================================
178 PARAMETER ( ZERO = 0.0E+0, ONE = 1.0E+0 )
180 * .. Local Scalars ..
181 INTEGER J, K, K1, I1, I2
184 * .. External Functions ..
186 INTEGER ISAMAX, ILAENV
187 EXTERNAL LSAME, ILAENV, ISAMAX
189 * .. External Subroutines ..
192 * .. Intrinsic Functions ..
195 * .. Executable Statements ..
200 * K1 is the first column of the panel to be factorized
201 * i.e., K1 is 2 for the first block column, and 1 for the rest of the blocks
205 IF( LSAME( UPLO, 'U' ) ) THEN
207 * .....................................................
208 * Factorize A as U**T*D*U using the upper triangle of A
209 * .....................................................
212 IF ( J.GT.MIN(M, NB) )
215 * K is the column to be factorized
216 * when being called from SSYTRF_AASEN,
217 * > for the first block column, J1 is 1, hence J1+J-1 is J,
218 * > for the rest of the columns, J1 is 2, and J1+J-1 is J+1,
222 * H(J:N, J) := A(J, J:N) - H(J:N, 1:(J-1)) * L(J1:(J-1), J),
223 * where H(J:N, J) has been initialized to be A(J, J:N)
227 * K is the column to be factorized
228 * > for the first block column, K is J, skipping the first two
230 * > for the rest of the columns, K is J+1, skipping only the
233 CALL SGEMV( 'No transpose', M-J+1, J-K1,
234 $ -ONE, H( J, K1 ), LDH,
236 $ ONE, H( J, J ), 1 )
239 * Copy H(i:n, i) into WORK
241 CALL SCOPY( M-J+1, H( J, J ), 1, WORK( 1 ), 1 )
245 * Compute WORK := WORK - L(J-1, J:N) * T(J-1,J),
246 * where A(J-1, J) stores T(J-1, J) and A(J-2, J:N) stores U(J-1, J:N)
249 CALL SAXPY( M-J+1, ALPHA, A( K-2, J ), LDA, WORK( 1 ), 1 )
252 * Set A(J, J) = T(J, J)
254 A( K, J ) = WORK( 1 )
258 * Compute WORK(2:N) = T(J, J) L(J, (J+1):N)
259 * where A(J, J) stores T(J, J) and A(J-1, (J+1):N) stores U(J, (J+1):N)
261 IF( (J1+J-1).GT.1 ) THEN
263 CALL SAXPY( M-J, ALPHA, A( K-1, J+1 ), LDA,
267 * Find max(|WORK(2:n)|)
269 I2 = ISAMAX( M-J, WORK( 2 ), 1 ) + 1
272 * Apply symmetric pivot
274 IF( (I2.NE.2) .AND. (PIV.NE.0) ) THEN
276 * Swap WORK(I1) and WORK(I2)
279 WORK( I2 ) = WORK( I1 )
282 * Swap A(I1, I1+1:N) with A(I1+1:N, I2)
286 CALL SSWAP( I2-I1-1, A( J1+I1-1, I1+1 ), LDA,
287 $ A( J1+I1, I2 ), 1 )
289 * Swap A(I1, I2+1:N) with A(I2, I2+1:N)
291 CALL SSWAP( M-I2, A( J1+I1-1, I2+1 ), LDA,
292 $ A( J1+I2-1, I2+1 ), LDA )
294 * Swap A(I1, I1) with A(I2,I2)
296 PIV = A( I1+J1-1, I1 )
297 A( J1+I1-1, I1 ) = A( J1+I2-1, I2 )
298 A( J1+I2-1, I2 ) = PIV
300 * Swap H(I1, 1:J1) with H(I2, 1:J1)
302 CALL SSWAP( I1-1, H( I1, 1 ), LDH, H( I2, 1 ), LDH )
305 IF( I1.GT.(K1-1) ) THEN
307 * Swap L(1:I1-1, I1) with L(1:I1-1, I2),
308 * skipping the first column
310 CALL SSWAP( I1-K1+1, A( 1, I1 ), 1,
317 * Set A(J, J+1) = T(J, J+1)
319 A( K, J+1 ) = WORK( 2 )
320 IF( (A( K, J ).EQ.ZERO ) .AND.
321 $ ( (J.EQ.M) .OR. (A( K, J+1 ).EQ.ZERO))) THEN
329 * Copy A(J+1:N, J+1) into H(J:N, J),
331 CALL SCOPY( M-J, A( K+1, J+1 ), LDA,
335 * Compute L(J+2, J+1) = WORK( 3:N ) / T(J, J+1),
336 * where A(J, J+1) = T(J, J+1) and A(J+2:N, J) = L(J+2:N, J+1)
338 IF( A( K, J+1 ).NE.ZERO ) THEN
339 ALPHA = ONE / A( K, J+1 )
340 CALL SCOPY( M-J-1, WORK( 3 ), 1, A( K, J+2 ), LDA )
341 CALL SSCAL( M-J-1, ALPHA, A( K, J+2 ), LDA )
343 CALL SLASET( 'Full', 1, M-J-1, ZERO, ZERO,
347 IF( (A( K, J ).EQ.ZERO) .AND. (INFO.EQ.0) ) THEN
357 * .....................................................
358 * Factorize A as L*D*L**T using the lower triangle of A
359 * .....................................................
362 IF( J.GT.MIN( M, NB ) )
365 * K is the column to be factorized
366 * when being called from SSYTRF_AASEN,
367 * > for the first block column, J1 is 1, hence J1+J-1 is J,
368 * > for the rest of the columns, J1 is 2, and J1+J-1 is J+1,
372 * H(J:N, J) := A(J:N, J) - H(J:N, 1:(J-1)) * L(J, J1:(J-1))^T,
373 * where H(J:N, J) has been initialized to be A(J:N, J)
377 * K is the column to be factorized
378 * > for the first block column, K is J, skipping the first two
380 * > for the rest of the columns, K is J+1, skipping only the
383 CALL SGEMV( 'No transpose', M-J+1, J-K1,
384 $ -ONE, H( J, K1 ), LDH,
386 $ ONE, H( J, J ), 1 )
389 * Copy H(J:N, J) into WORK
391 CALL SCOPY( M-J+1, H( J, J ), 1, WORK( 1 ), 1 )
395 * Compute WORK := WORK - L(J:N, J-1) * T(J-1,J),
396 * where A(J-1, J) = T(J-1, J) and A(J, J-2) = L(J, J-1)
399 CALL SAXPY( M-J+1, ALPHA, A( J, K-2 ), 1, WORK( 1 ), 1 )
402 * Set A(J, J) = T(J, J)
404 A( J, K ) = WORK( 1 )
408 * Compute WORK(2:N) = T(J, J) L((J+1):N, J)
409 * where A(J, J) = T(J, J) and A((J+1):N, J-1) = L((J+1):N, J)
411 IF( (J1+J-1).GT.1 ) THEN
413 CALL SAXPY( M-J, ALPHA, A( J+1, K-1 ), 1,
417 * Find max(|WORK(2:n)|)
419 I2 = ISAMAX( M-J, WORK( 2 ), 1 ) + 1
422 * Apply symmetric pivot
424 IF( (I2.NE.2) .AND. (PIV.NE.0) ) THEN
426 * Swap WORK(I1) and WORK(I2)
429 WORK( I2 ) = WORK( I1 )
432 * Swap A(I1+1:N, I1) with A(I2, I1+1:N)
436 CALL SSWAP( I2-I1-1, A( I1+1, J1+I1-1 ), 1,
437 $ A( I2, J1+I1 ), LDA )
439 * Swap A(I2+1:N, I1) with A(I2+1:N, I2)
441 CALL SSWAP( M-I2, A( I2+1, J1+I1-1 ), 1,
442 $ A( I2+1, J1+I2-1 ), 1 )
444 * Swap A(I1, I1) with A(I2, I2)
446 PIV = A( I1, J1+I1-1 )
447 A( I1, J1+I1-1 ) = A( I2, J1+I2-1 )
448 A( I2, J1+I2-1 ) = PIV
450 * Swap H(I1, I1:J1) with H(I2, I2:J1)
452 CALL SSWAP( I1-1, H( I1, 1 ), LDH, H( I2, 1 ), LDH )
455 IF( I1.GT.(K1-1) ) THEN
457 * Swap L(1:I1-1, I1) with L(1:I1-1, I2),
458 * skipping the first column
460 CALL SSWAP( I1-K1+1, A( I1, 1 ), LDA,
467 * Set A(J+1, J) = T(J+1, J)
469 A( J+1, K ) = WORK( 2 )
470 IF( (A( J, K ).EQ.ZERO) .AND.
471 $ ( (J.EQ.M) .OR. (A( J+1, K ).EQ.ZERO)) ) THEN
478 * Copy A(J+1:N, J+1) into H(J+1:N, J),
480 CALL SCOPY( M-J, A( J+1, K+1 ), 1,
484 * Compute L(J+2, J+1) = WORK( 3:N ) / T(J, J+1),
485 * where A(J, J+1) = T(J, J+1) and A(J+2:N, J) = L(J+2:N, J+1)
487 IF( A( J+1, K ).NE.ZERO ) THEN
488 ALPHA = ONE / A( J+1, K )
489 CALL SCOPY( M-J-1, WORK( 3 ), 1, A( J+2, K ), 1 )
490 CALL SSCAL( M-J-1, ALPHA, A( J+2, K ), 1 )
492 CALL SLASET( 'Full', M-J-1, 1, ZERO, ZERO,
496 IF( (A( J, K ).EQ.ZERO) .AND. (INFO.EQ.0) ) THEN
506 * End of SLASYF_AASEN