SCALAPACK 2.2.2
LAPACK: Linear Algebra PACKage
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◆ pcdtlaschk()

subroutine pcdtlaschk ( character  symm,
character  uplo,
character  trans,
integer  n,
integer  bwl,
integer  bwu,
integer  nrhs,
complex, dimension( * )  x,
integer  ix,
integer  jx,
integer, dimension( * )  descx,
integer  iaseed,
complex, dimension( * )  a,
integer  ia,
integer  ja,
integer, dimension( * )  desca,
integer  ibseed,
real  anorm,
real  resid,
complex, dimension( * )  work,
integer  worksiz 
)

Definition at line 1 of file pcdtlaschk.f.

4*
5*
6* -- ScaLAPACK routine (version 1.7) --
7* University of Tennessee, Knoxville, Oak Ridge National Laboratory,
8* and University of California, Berkeley.
9* November 15, 1997
10*
11* .. Scalar Arguments ..
12 CHARACTER SYMM, TRANS, UPLO
13 INTEGER BWL, BWU, IA, IASEED, IBSEED,
14 $ IX, JA, JX, N, NRHS, WORKSIZ
15 REAL ANORM, RESID
16* ..
17* .. Array Arguments ..
18 INTEGER DESCA( * ), DESCX( * )
19 COMPLEX A( * ), WORK( * ), X( * )
20* .. External Functions ..
21 LOGICAL LSAME
22* ..
23*
24* Purpose
25* =======
26*
27* PCDTLASCHK computes the residual
28* || sub( A )*sub( X ) - B || / (|| sub( A ) ||*|| sub( X ) ||*eps*N)
29* to check the accuracy of the factorization and solve steps in the
30* LU and Cholesky decompositions, where sub( A ) denotes
31* A(IA:IA+N-1,JA,JA+N-1), sub( X ) denotes X(IX:IX+N-1, JX:JX+NRHS-1).
32*
33* Notes
34* =====
35*
36* Each global data object is described by an associated description
37* vector. This vector stores the information required to establish
38* the mapping between an object element and its corresponding process
39* and memory location.
40*
41* Let A be a generic term for any 2D block cyclicly distributed array.
42* Such a global array has an associated description vector DESCA.
43* In the following comments, the character _ should be read as
44* "of the global array".
45*
46* NOTATION STORED IN EXPLANATION
47* --------------- -------------- --------------------------------------
48* DTYPE_A(global) DESCA( DTYPE_ )The descriptor type. In this case,
49* DTYPE_A = 1.
50* CTXT_A (global) DESCA( CTXT_ ) The BLACS context handle, indicating
51* the BLACS process grid A is distribu-
52* ted over. The context itself is glo-
53* bal, but the handle (the integer
54* value) may vary.
55* M_A (global) DESCA( M_ ) The number of rows in the global
56* array A.
57* N_A (global) DESCA( N_ ) The number of columns in the global
58* array A.
59* MB_A (global) DESCA( MB_ ) The blocking factor used to distribute
60* the rows of the array.
61* NB_A (global) DESCA( NB_ ) The blocking factor used to distribute
62* the columns of the array.
63* RSRC_A (global) DESCA( RSRC_ ) The process row over which the first
64* row of the array A is distributed.
65* CSRC_A (global) DESCA( CSRC_ ) The process column over which the
66* first column of the array A is
67* distributed.
68* LLD_A (local) DESCA( LLD_ ) The leading dimension of the local
69* array. LLD_A >= MAX(1,LOCr(M_A)).
70*
71* Let K be the number of rows or columns of a distributed matrix,
72* and assume that its process grid has dimension p x q.
73* LOCr( K ) denotes the number of elements of K that a process
74* would receive if K were distributed over the p processes of its
75* process column.
76* Similarly, LOCc( K ) denotes the number of elements of K that a
77* process would receive if K were distributed over the q processes of
78* its process row.
79* The values of LOCr() and LOCc() may be determined via a call to the
80* ScaLAPACK tool function, NUMROC:
81* LOCr( M ) = NUMROC( M, MB_A, MYROW, RSRC_A, NPROW ),
82* LOCc( N ) = NUMROC( N, NB_A, MYCOL, CSRC_A, NPCOL ).
83* An upper bound for these quantities may be computed by:
84* LOCr( M ) <= ceil( ceil(M/MB_A)/NPROW )*MB_A
85* LOCc( N ) <= ceil( ceil(N/NB_A)/NPCOL )*NB_A
86*
87* Arguments
88* =========
89*
90* SYMM (global input) CHARACTER
91* if SYMM = 'H', sub( A ) is a hermitian distributed band
92* matrix, otherwise sub( A ) is a general distributed matrix.
93*
94* UPLO (global input) CHARACTER
95* if SYMM = 'H', then
96* if UPLO = 'L', the lower half of the matrix is stored
97* if UPLO = 'U', the upper half of the matrix is stored
98* if SYMM != 'S' or 'H', then
99* if UPLO = 'D', the matrix is stable during factorization
100* without interchanges
101* if UPLO != 'D', the matrix is general
102*
103* TRANS if TRANS= 'C', A 'Conjugate transpose' is used as the
104* coefficient matrix in the solve.
105*
106* N (global input) INTEGER
107* The number of columns to be operated on, i.e. the number of
108* columns of the distributed submatrix sub( A ). N >= 0.
109*
110* NRHS (global input) INTEGER
111* The number of right-hand-sides, i.e the number of columns
112* of the distributed matrix sub( X ). NRHS >= 1.
113*
114* X (local input) COMPLEX pointer into the local memory
115* to an array of dimension (LLD_X,LOCq(JX+NRHS-1). This array
116* contains the local pieces of the answer vector(s) sub( X ) of
117* sub( A ) sub( X ) - B, split up over a column of processes.
118*
119* IX (global input) INTEGER
120* The row index in the global array X indicating the first
121* row of sub( X ).
122*
123* DESCX (global and local input) INTEGER array of dimension DLEN_.
124* The array descriptor for the distributed matrix X.
125*
126* IASEED (global input) INTEGER
127* The seed number to generate the original matrix Ao.
128*
129* JA (global input) INTEGER
130* The column index in the global array A indicating the
131* first column of sub( A ).
132*
133* DESCA (global and local input) INTEGER array of dimension DLEN_.
134* The array descriptor for the distributed matrix A.
135*
136* IBSEED (global input) INTEGER
137* The seed number to generate the original matrix B.
138*
139* ANORM (global input) REAL
140* The 1-norm or infinity norm of the distributed matrix
141* sub( A ).
142*
143* RESID (global output) REAL
144* The residual error:
145* ||sub( A )*sub( X )-B|| / (||sub( A )||*||sub( X )||*eps*N).
146*
147* WORK (local workspace) COMPLEX array, dimension (LWORK)
148* IF SYMM='S'
149* LWORK >= max(5,NB)+2*NB
150* IF SYMM!='S' or 'H'
151* LWORK >= max(5,NB)+2*NB
152*
153* WORKSIZ (local input) size of WORK.
154*
155* =====================================================================
156*
157* Code Developer: Andrew J. Cleary, University of Tennessee.
158* Current address: Lawrence Livermore National Labs.
159* This version released: August, 2001.
160*
161* =====================================================================
162*
163* .. Parameters ..
164 COMPLEX ZERO, ONE
165 parameter( one = ( 1.0e+0, 0.0e+0 ),
166 $ zero = ( 0.0e+0, 0.0e+0 ) )
167 INTEGER BLOCK_CYCLIC_2D, CSRC_, CTXT_, DLEN_, DTYPE_,
168 $ LLD_, MB_, M_, NB_, N_, RSRC_
169 parameter( block_cyclic_2d = 1, dlen_ = 9, dtype_ = 1,
170 $ ctxt_ = 2, m_ = 3, n_ = 4, mb_ = 5, nb_ = 6,
171 $ rsrc_ = 7, csrc_ = 8, lld_ = 9 )
172 INTEGER INT_ONE
173 parameter( int_one = 1 )
174* ..
175* .. Local Scalars ..
176 INTEGER IACOL, IAROW, ICTXT,
177 $ IIA, IIX, IPB, IPW,
178 $ IXCOL, IXROW, J, JJA, JJX, LDA,
179 $ MYCOL, MYROW, NB, NP, NPCOL, NPROW, NQ
180 INTEGER I, START
181 INTEGER BW, INFO, IPPRODUCT, WORK_MIN
182 REAL DIVISOR, EPS, RESID1, NORMX
183* ..
184* .. Local Arrays ..
185* ..
186* .. External Subroutines ..
187 EXTERNAL blacs_gridinfo, cgamx2d, cgemm, cgsum2d,
188 $ claset, pbctran, pcmatgen, sgebr2d,
189 $ sgebs2d, sgerv2d, sgesd2d
190* ..
191* .. External Functions ..
192 INTEGER ICAMAX, NUMROC
193 REAL PSLAMCH
194 EXTERNAL icamax, numroc, pslamch
195* ..
196* .. Intrinsic Functions ..
197 INTRINSIC abs, max, min, mod, real
198* ..
199* .. Executable Statements ..
200*
201* Get needed initial parameters
202*
203 ictxt = desca( ctxt_ )
204 nb = desca( nb_ )
205*
206 IF( lsame( symm, 'H' ) ) THEN
207 bw = bwl
208 start = 1
209 work_min = max(5,nb)+2*nb
210 ELSE
211 bw = max(bwl, bwu)
212 IF( lsame( uplo, 'D' )) THEN
213 start = 1
214 ELSE
215 start = 2
216 ENDIF
217 work_min = max(5,nb)+2*nb
218 ENDIF
219*
220 IF ( worksiz .LT. work_min ) THEN
221 CALL pxerbla( ictxt, 'PCTLASCHK', -18 )
222 RETURN
223 END IF
224*
225 CALL blacs_gridinfo( ictxt, nprow, npcol, myrow, mycol )
226*
227 eps = pslamch( ictxt, 'eps' )
228 resid = 0.0e+0
229 divisor = anorm * eps * real( n )
230*
231 CALL infog2l( ia, ja, desca, nprow, npcol, myrow, mycol, iia, jja,
232 $ iarow, iacol )
233 CALL infog2l( ix, jx, descx, nprow, npcol, myrow, mycol, iix, jjx,
234 $ ixrow, ixcol )
235 np = numroc( (3), desca( mb_ ), myrow, 0, nprow )
236 nq = numroc( n, desca( nb_ ), mycol, 0, npcol )
237*
238 ipb = 1
239 ipproduct = 1 + desca( nb_ )
240 ipw = 1 + 2*desca( nb_ )
241*
242 lda = desca( lld_ )
243*
244* Regenerate A
245*
246 IF( lsame( symm, 'H' )) THEN
247 CALL pcbmatgen( ictxt, uplo, 'D', bw, bw, n, bw+1,
248 $ desca( nb_ ), a, desca( lld_ ), 0, 0,
249 $ iaseed, myrow, mycol, nprow, npcol )
250 ELSE
251*
252 CALL pcbmatgen( ictxt, 'N', uplo, bwl, bwu, n,
253 $ desca( mb_ ), desca( nb_ ), a,
254 $ desca( lld_ ), 0, 0, iaseed, myrow,
255 $ mycol, nprow, npcol )
256 ENDIF
257*
258* Matrix formed above has the diagonals shifted from what was
259* input to the tridiagonal routine. Shift them back.
260*
261* Send elements to neighboring processors
262*
263 IF( mycol.GT.0 ) THEN
264 CALL cgesd2d( ictxt, 1, 1, a( start+2), lda,
265 $ myrow, mycol-1 )
266 ENDIF
267*
268 IF( mycol.LT.npcol-1 ) THEN
269 CALL cgesd2d( ictxt, 1, 1,
270 $ a( start+( desca( nb_ )-1 )*lda ),
271 $ lda, myrow, mycol+1 )
272 ENDIF
273*
274* Shift local elements
275*
276 DO 220 i=0,desca( nb_ )-1
277 a( start+2+(i)*lda ) = a( start+2+(i+1)*lda )
278 220 CONTINUE
279*
280 DO 230 i=desca( nb_ )-1,0,-1
281 a( start+(i+1)*lda ) = a( start+(i)*lda )
282 230 CONTINUE
283*
284* Receive elements from neighboring processors
285*
286 IF( mycol.LT.npcol-1 ) THEN
287 CALL cgerv2d( ictxt, 1, 1,
288 $ a( start+2+( desca( nb_ )-1 )*lda ),
289 $ lda, myrow, mycol+1 )
290 ENDIF
291*
292 IF( mycol.GT.0 ) THEN
293 CALL cgerv2d( ictxt, 1, 1, a( start), lda,
294 $ myrow, mycol-1 )
295 ENDIF
296*
297* Loop over the rhs
298*
299 resid = 0.0
300*
301 DO 40 j = 1, nrhs
302*
303* Multiply A * current column of X
304*
305*
306 CALL pcgbdcmv( bwl+bwu+1, bwl, bwu, trans, n, a, 1, desca,
307 $ 1, x( 1 + (j-1)*descx( lld_ )), 1, descx,
308 $ work( ipproduct ), work( ipw ),
309 $ (int_one+2)*int_one, info )
310*
311*
312* Regenerate column of B
313*
314 CALL pcmatgen( descx( ctxt_ ), 'No', 'No', descx( m_ ),
315 $ descx( n_ ), descx( mb_ ), descx( nb_ ),
316 $ work( ipb ), descx( lld_ ), descx( rsrc_ ),
317 $ descx( csrc_ ), ibseed, 0, nq, j-1, 1, mycol,
318 $ myrow, npcol, nprow )
319*
320* Figure || A * X - B || & || X ||
321*
322 CALL pcaxpy( n, -one, work( ipproduct ), 1, 1, descx, 1,
323 $ work( ipb ), 1, 1, descx, 1 )
324*
325 CALL pscnrm2( n, normx,
326 $ x, 1, j, descx, 1 )
327*
328 CALL pscnrm2( n, resid1,
329 $ work( ipb ), 1, 1, descx, 1 )
330*
331*
332* Calculate residual = ||Ax-b|| / (||x||*||A||*eps*N)
333*
334 resid1 = resid1 / ( normx*divisor )
335*
336 resid = max( resid, resid1 )
337*
338 40 CONTINUE
339*
340 RETURN
341*
342* End of PCTLASCHK
343*
pcmatgen
subroutine pcmatgen(ictxt, aform, diag, m, n, mb, nb, a, lda, iarow, iacol, iseed, iroff, irnum, icoff, icnum, myrow, mycol, nprow, npcol)
Definition pcmatgen.f:4
infog2l
subroutine infog2l(grindx, gcindx, desc, nprow, npcol, myrow, mycol, lrindx, lcindx, rsrc, csrc)
Definition infog2l.f:3
numroc
integer function numroc(n, nb, iproc, isrcproc, nprocs)
Definition numroc.f:2
pbctran
subroutine pbctran(icontxt, adist, trans, m, n, nb, a, lda, beta, c, ldc, iarow, iacol, icrow, iccol, work)
Definition pbctran.f:3
pslamch
real function pslamch(ictxt, cmach)
Definition pcblastst.f:7455
pcbmatgen
subroutine pcbmatgen(ictxt, aform, aform2, bwl, bwu, n, mb, nb, a, lda, iarow, iacol, iseed, myrow, mycol, nprow, npcol)
Definition pcbmatgen.f:5
pcgbdcmv
subroutine pcgbdcmv(ldbw, bwl, bwu, trans, n, a, ja, desca, nrhs, b, ib, descb, x, work, lwork, info)
Definition pcdbmv1.f:3
max
#define max(A, B)
Definition pcgemr.c:180
min
#define min(A, B)
Definition pcgemr.c:181
pxerbla
subroutine pxerbla(ictxt, srname, info)
Definition pxerbla.f:2
lsame
logical function lsame(ca, cb)
Definition tools.f:1724
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