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source: Sophya/trunk/SophyaExt/LinAlg/intflapack.cc@ 1494

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Last change on this file since 1494 was 1494, checked in by ansari, 24 years ago
Ajout LeastSquareSolve - Reza 15/5/2001
File size: 13.8 KB

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1	#include <iostream.h>
2	#include "intflapack.h"
3	#include "tvector.h"
4	#include "tmatrix.h"
5	#include <typeinfo>
6
7	/*!
8	\defgroup LinAlg LinAlg module
9	This module contains classes and functions for complex linear
10	algebra on arrays. This module is intended mainly to have
11	classes implementing C++ interfaces between Sophya objects
12	and external linear algebra libraries, such as LAPACK.
13	*/
14
15	/*!
16	\class SOPHYA::LapackServer
17	\ingroup LinAlg
18	This class implements an interface to LAPACK library driver routines.
19	The LAPACK (Linear Algebra PACKage) is a collection high performance
20	routines to solve common problems in numerical linear algebra.
21	its is available from http://www.netlib.org.
22
23	The present version of our LapackServer (Feb 2001) provides only
24	interfaces for the linear system solver and singular value
25	decomposition (SVD). Only arrays with BaseArray::FortranMemoryMapping
26	can be handled by LapackServer. LapackServer can be instanciated
27	for simple and double precision real or complex array types.
28
29	The example below shows solving a linear system A*X = B
30
31	\code
32	#include "intflapack.h"
33	// ...
34	// Use FortranMemoryMapping as default
35	BaseArray::SetDefaultMemoryMapping(BaseArray::FortranMemoryMapping);
36	// Create an fill the arrays A and B
37	int n = 20;
38	Matrix A(n, n);
39	A = RandomSequence();
40	Vector X(n),B(n);
41	X = RandomSequence();
42	B = A*X;
43	// Solve the linear system A*X = B
44	LapackServer<r_8> lps;
45	lps.LinSolve(A,B);
46	// We get the result in B, which should be equal to X ...
47	// Compute the difference B-X ;
48	Vector diff = B-X;
49	\endcode
50
51	*/
52
53	extern "C" {
54	// Drivers pour resolution de systemes lineaires
55	void sgesv_(int_4* n, int_4* nrhs, r_4* a, int_4* lda,
56	int_4* ipiv, r_4* b, int_4* ldb, int_4* info);
57	void dgesv_(int_4* n, int_4* nrhs, r_8* a, int_4* lda,
58	int_4* ipiv, r_8* b, int_4* ldb, int_4* info);
59	void cgesv_(int_4* n, int_4* nrhs, complex<r_4>* a, int_4* lda,
60	int_4* ipiv, complex<r_4>* b, int_4* ldb, int_4* info);
61	void zgesv_(int_4* n, int_4* nrhs, complex<r_8>* a, int_4* lda,
62	int_4* ipiv, complex<r_8>* b, int_4* ldb, int_4* info);
63
64	// Driver pour resolution de systemes au sens de Xi2
65	void sgels_(char * trans, int_4* m, int_4* n, int_4* nrhs, r_4* a, int_4* lda,
66	r_4* b, int_4* ldb, r_4* work, int_4* lwork, int_4* info);
67	void dgels_(char * trans, int_4* m, int_4* n, int_4* nrhs, r_8* a, int_4* lda,
68	r_8* b, int_4* ldb, r_8* work, int_4* lwork, int_4* info);
69	void cgels_(char * trans, int_4* m, int_4* n, int_4* nrhs, complex<r_4>* a, int_4* lda,
70	complex<r_4>* b, int_4* ldb, complex<r_4>* work, int_4* lwork, int_4* info);
71	void zgels_(char * trans, int_4* m, int_4* n, int_4* nrhs, complex<r_8>* a, int_4* lda,
72	complex<r_8>* b, int_4* ldb, complex<r_8>* work, int_4* lwork, int_4* info);
73
74	// Driver pour decomposition SVD
75	void sgesvd_(char* jobu, char* jobvt, int_4* m, int_4* n, r_4* a, int_4* lda,
76	r_4* s, r_4* u, int_4* ldu, r_4* vt, int_4* ldvt,
77	r_4* work, int_4* lwork, int_4* info);
78	void dgesvd_(char* jobu, char* jobvt, int_4* m, int_4* n, r_8* a, int_4* lda,
79	r_8* s, r_8* u, int_4* ldu, r_8* vt, int_4* ldvt,
80	r_8* work, int_4* lwork, int_4* info);
81	void cgesvd_(char* jobu, char* jobvt, int_4* m, int_4* n, complex<r_4>* a, int_4* lda,
82	complex<r_4>* s, complex<r_4>* u, int_4* ldu, complex<r_4>* vt, int_4* ldvt,
83	complex<r_4>* work, int_4* lwork, int_4* info);
84	void zgesvd_(char* jobu, char* jobvt, int_4* m, int_4* n, complex<r_8>* a, int_4* lda,
85	complex<r_8>* s, complex<r_8>* u, int_4* ldu, complex<r_8>* vt, int_4* ldvt,
86	complex<r_8>* work, int_4* lwork, int_4* info);
87
88	}
89
90
91	// -------------- Classe LapackServer<T> --------------
92
93	template <class T>
94	LapackServer<T>::LapackServer()
95	{
96	SetWorkSpaceSizeFactor();
97	}
98
99	template <class T>
100	LapackServer<T>::~LapackServer()
101	{
102	}
103
104	//! Interface to Lapack linear system solver driver s/d/c/zgesvd().
105	/! Solve the linear system a x = b. Input arrays
106	should have FortranMemory mapping (column packed).
107	\param a : input matrix, overwritten on output
108	\param b : input-output, input vector b, contains x on exit
109	\return : return code from lapack driver _gesv()
110	*/
111	template <class T>
112	int LapackServer<T>::LinSolve(TArray<T>& a, TArray<T> & b)
113	{
114	if ( ( a.NbDimensions() != 2 ) \|\| ( b.NbDimensions() != 2 ) )
115	throw(SzMismatchError("LapackServer::LinSolve(a,b) a Or b NbDimensions() != 2"));
116
117	int_4 rowa = a.RowsKA();
118	int_4 cola = a.ColsKA();
119	int_4 rowb = b.RowsKA();
120	int_4 colb = b.ColsKA();
121	if ( a.Size(rowa) != a.Size(cola))
122	throw(SzMismatchError("LapackServer::LinSolve(a,b) a Not a square Array"));
123	if ( a.Size(rowa) != b.Size(rowb))
124	throw(SzMismatchError("LapackServer::LinSolve(a,b) RowSize(a <> b) "));
125
126	if (!a.IsPacked(rowa) \|\| !b.IsPacked(rowb))
127	throw(SzMismatchError("LapackServer::LinSolve(a,b) a Or b Not Column Packed"));
128
129	int_4 n = a.Size(rowa);
130	int_4 nrhs = b.Size(colb);
131	int_4 lda = a.Step(cola);
132	int_4 ldb = b.Step(colb);
133	int_4 info;
134	int_4* ipiv = new int_4[n];
135
136	if (typeid(T) == typeid(r_4) )
137	sgesv_(&n, &nrhs, (r_4 )a.Data(), &lda, ipiv, (r_4 )b.Data(), &ldb, &info);
138	else if (typeid(T) == typeid(r_8) )
139	dgesv_(&n, &nrhs, (r_8 )a.Data(), &lda, ipiv, (r_8 )b.Data(), &ldb, &info);
140	else if (typeid(T) == typeid(complex<r_4>) )
141	cgesv_(&n, &nrhs, (complex<r_4> *)a.Data(), &lda, ipiv,
142	(complex<r_4> *)b.Data(), &ldb, &info);
143	else if (typeid(T) == typeid(complex<r_8>) )
144	zgesv_(&n, &nrhs, (complex<r_8> *)a.Data(), &lda, ipiv,
145	(complex<r_8> *)b.Data(), &ldb, &info);
146	else {
147	delete[] ipiv;
148	string tn = typeid(T).name();
149	cerr << " LapackServer::LinSolve(a,b) - Unsupported DataType T = " << tn << endl;
150	throw TypeMismatchExc("LapackServer::LinSolve(a,b) - Unsupported DataType (T)");
151	}
152	delete[] ipiv;
153	return(info);
154	}
155
156	template <class T>
157	int LapackServer<T>::LeastSquareSolve(TArray<T>& a, TArray<T> & b)
158	{
159	if ( ( a.NbDimensions() != 2 ) \|\| ( b.NbDimensions() != 2 ) )
160	throw(SzMismatchError("LapackServer::LinSolve(a,b) a Or b NbDimensions() != 2"));
161
162	int_4 rowa = a.RowsKA();
163	int_4 cola = a.ColsKA();
164	int_4 rowb = b.RowsKA();
165	int_4 colb = b.ColsKA();
166
167
168	if ( a.Size(rowa) != b.Size(rowb))
169	throw(SzMismatchError("LapackServer::LeastSquareSolve(a,b) RowSize(a <> b) "));
170
171	if (!a.IsPacked(rowa) \|\| !b.IsPacked(rowb))
172	throw(SzMismatchError("LapackServer::LinSolve(a,b) a Or b Not Column Packed"));
173
174	if ( a.Size(rowa) < a.Size(cola))
175	throw(SzMismatchError("LapackServer::LeastSquareSolve(a,b) NRows<NCols "));
176
177	int_4 m = a.Size(rowa);
178	int_4 n = a.Size(cola);
179	int_4 nrhs = b.Size(colb);
180
181	int_4 lda = a.Step(cola);
182	int_4 ldb = b.Step(colb);
183	int_4 info;
184
185	int_4 minmn = (m < n) ? m : n;
186	int_4 maxmn = (m > n) ? m : n;
187	int_4 maxmnrhs = (nrhs > maxmn) ? nrhs : maxmn;
188	if (maxmnrhs < 1) maxmnrhs = 1;
189
190	int_4 lwork = minmn+maxmnrhs*5;
191	T * work = new T[lwork];
192
193	char trans = 'N';
194
195	if (typeid(T) == typeid(r_4) )
196	sgels_(&trans, &m, &n, &nrhs, (r_4 *)a.Data(), &lda,
197	(r_4 )b.Data(), &ldb, (r_4 )work, &lwork, &info);
198	else if (typeid(T) == typeid(r_8) )
199	dgels_(&trans, &m, &n, &nrhs, (r_8 *)a.Data(), &lda,
200	(r_8 )b.Data(), &ldb, (r_8 )work, &lwork, &info);
201	else if (typeid(T) == typeid(complex<r_4>) )
202	cgels_(&trans, &m, &n, &nrhs, (complex<r_4> *)a.Data(), &lda,
203	(complex<r_4> )b.Data(), &ldb, (complex<r_4> )work, &lwork, &info);
204	else if (typeid(T) == typeid(complex<r_8>) )
205	zgels_(&trans, &m, &n, &nrhs, (complex<r_8> *)a.Data(), &lda,
206	(complex<r_8> )b.Data(), &ldb, (complex<r_8> )work, &lwork, &info);
207	else {
208	delete[] work;
209	string tn = typeid(T).name();
210	cerr << " LapackServer::LeastSquareSolve(a,b) - Unsupported DataType T = " << tn << endl;
211	throw TypeMismatchExc("LapackServer::LeastSquareSolve(a,b) - Unsupported DataType (T)");
212	}
213	delete[] work;
214	return(info);
215	}
216
217
218	//! Interface to Lapack SVD driver s/d/c/zgesv().
219	/*! Computes the vector of singular values of \b a. Input arrays
220	should have FortranMemoryMapping (column packed).
221	\param a : input m-by-n matrix
222	\param s : Vector of min(m,n) singular values (descending order)
223	\return : return code from lapack driver _gesvd()
224	*/
225
226	template <class T>
227	int LapackServer<T>::SVD(TArray<T>& a, TArray<T> & s)
228	{
229	return (SVDDriver(a, s, NULL, NULL) );
230	}
231
232	//! Interface to Lapack SVD driver s/d/c/zgesv().
233	/*! Computes the vector of singular values of \b a, as well as
234	right and left singular vectors of \b a.
235	\f[
236	A = U \Sigma V^T , ( A = U \Sigma V^H \ complex)
237	\f]
238	\f[
239	A v_i = \sigma_i u_i \ and A^T u_i = \sigma_i v_i \ (A^H \ complex)
240	\f]
241	U and V are orthogonal (unitary) matrices.
242	\param a : input m-by-n matrix (in FotranMemoryMapping)
243	\param s : Vector of min(m,n) singular values (descending order)
244	\param u : Matrix of left singular vectors
245	\param vt : Transpose of right singular vectors.
246	\return : return code from lapack driver _gesvd()
247	*/
248	template <class T>
249	int LapackServer<T>::SVD(TArray<T>& a, TArray<T> & s, TArray<T> & u, TArray<T> & vt)
250	{
251	return (SVDDriver(a, s, &u, &vt) );
252	}
253
254
255	//! Interface to Lapack SVD driver s/d/c/zgesv().
256	template <class T>
257	int LapackServer<T>::SVDDriver(TArray<T>& a, TArray<T> & s, TArray<T>* up, TArray<T>* vtp)
258	{
259	if ( ( a.NbDimensions() != 2 ) )
260	throw(SzMismatchError("LapackServer::SVD(a, ...) a.NbDimensions() != 2"));
261
262	int_4 rowa = a.RowsKA();
263	int_4 cola = a.ColsKA();
264
265	if ( !a.IsPacked(rowa) )
266	throw(SzMismatchError("LapackServer::SVD(a, ...) a Not Column Packed "));
267
268	int_4 m = a.Size(rowa);
269	int_4 n = a.Size(cola);
270	int_4 maxmn = (m > n) ? m : n;
271	int_4 minmn = (m < n) ? m : n;
272
273	char jobu, jobvt;
274	jobu = 'N';
275	jobvt = 'N';
276
277	sa_size_t sz[2];
278	if ( up != NULL) {
279	if ( dynamic_cast< TVector<T> * > (vtp) )
280	throw( TypeMismatchExc("LapackServer::SVD() Wrong type (=TVector<T>) for u !") );
281	up->SetMemoryMapping(BaseArray::FortranMemoryMapping);
282	sz[0] = sz[1] = m;
283	up->ReSize(2, sz );
284	jobu = 'A';
285	}
286	else {
287	up = new TMatrix<T>(1,1);
288	jobu = 'N';
289	}
290	if ( vtp != NULL) {
291	if ( dynamic_cast< TVector<T> * > (vtp) )
292	throw( TypeMismatchExc("LapackServer::SVD() Wrong type (=TVector<T>) for vt !") );
293	vtp->SetMemoryMapping(BaseArray::FortranMemoryMapping);
294	sz[0] = sz[1] = n;
295	vtp->ReSize(2, sz );
296	jobvt = 'A';
297	}
298	else {
299	vtp = new TMatrix<T>(1,1);
300	jobvt = 'N';
301	}
302
303	TVector<T> vs = dynamic_cast< TVector<T> > (&s);
304	if (vs) vs->ReSize(minmn);
305	else {
306	TMatrix<T> ms = dynamic_cast< TMatrix<T> > (&s);
307	if (ms) ms->ReSize(minmn,1);
308	else {
309	sz[0] = minmn; sz[1] = 1;
310	s.ReSize(1, sz);
311	}
312	}
313
314	int_4 lda = a.Step(a.ColsKA());
315	int_4 ldu = up->Step(up->ColsKA());
316	int_4 ldvt = vtp->Step(vtp->ColsKA());
317
318	int_4 lwork = maxmn5wspace_size_factor;
319	T * work = new T[lwork];
320	int_4 info;
321
322	if (typeid(T) == typeid(r_4) )
323	sgesvd_(&jobu, &jobvt, &m, &n, (r_4 *)a.Data(), &lda,
324	(r_4 )s.Data(), (r_4 ) up->Data(), &ldu, (r_4 *)vtp->Data(), &ldvt,
325	(r_4 *)work, &lwork, &info);
326	else if (typeid(T) == typeid(r_8) )
327	dgesvd_(&jobu, &jobvt, &m, &n, (r_8 *)a.Data(), &lda,
328	(r_8 )s.Data(), (r_8 ) up->Data(), &ldu, (r_8 *)vtp->Data(), &ldvt,
329	(r_8 *)work, &lwork, &info);
330	else if (typeid(T) == typeid(complex<r_4>) )
331	cgesvd_(&jobu, &jobvt, &m, &n, (complex<r_4> *)a.Data(), &lda,
332	(complex<r_4> )s.Data(), (complex<r_4> ) up->Data(), &ldu,
333	(complex<r_4> *)vtp->Data(), &ldvt,
334	(complex<r_4> *)work, &lwork, &info);
335	else if (typeid(T) == typeid(complex<r_8>) )
336	zgesvd_(&jobu, &jobvt, &m, &n, (complex<r_8> *)a.Data(), &lda,
337	(complex<r_8> )s.Data(), (complex<r_8> ) up->Data(), &ldu,
338	(complex<r_8> *)vtp->Data(), &ldvt,
339	(complex<r_8> *)work, &lwork, &info);
340	else {
341	if (jobu == 'N') delete up;
342	if (jobvt == 'N') delete vtp;
343	string tn = typeid(T).name();
344	cerr << " LapackServer::SVDDriver(...) - Unsupported DataType T = " << tn << endl;
345	throw TypeMismatchExc("LapackServer::LinSolve(a,b) - Unsupported DataType (T)");
346	}
347
348	if (jobu == 'N') delete up;
349	if (jobvt == 'N') delete vtp;
350	return(info);
351	}
352
353	void rztest_lapack(TArray<r_4>& aa, TArray<r_4>& bb)
354	{
355	if ( aa.NbDimensions() != 2 ) throw(SzMismatchError("rztest_lapack(TMatrix<r_4> A Not a Matrix"));
356	if ( aa.SizeX() != aa.SizeY()) throw(SzMismatchError("rztest_lapack(TMatrix<r_4> A Not a square Matrix"));
357	if ( bb.NbDimensions() != 2 ) throw(SzMismatchError("rztest_lapack(TMatrix<r_4> A Not a Matrix"));
358	if ( bb.SizeX() != aa.SizeX() ) throw(SzMismatchError("rztest_lapack(TMatrix<r_4> A <> B "));
359	if ( !bb.IsPacked() \|\| !bb.IsPacked() )
360	throw(SzMismatchError("rztest_lapack(TMatrix<r_4> Not packed A or B "));
361
362	int_4 n = aa.SizeX();
363	int_4 nrhs = bb.SizeY();
364	int_4 lda = n;
365	int_4 ldb = bb.SizeX();
366	int_4 info;
367	int_4* ipiv = new int_4[n];
368	sgesv_(&n, &nrhs, aa.Data(), &lda, ipiv, bb.Data(), &ldb, &info);
369	delete[] ipiv;
370	cout << "rztest_lapack/Info= " << info << endl;
371	cout << aa << "\n" << bb << endl;
372	return;
373	}
374
375	///////////////////////////////////////////////////////////////
376	#ifdef __CXX_PRAGMA_TEMPLATES__
377	#pragma define_template LapackServer<r_4>
378	#pragma define_template LapackServer<r_8>
379	#pragma define_template LapackServer< complex<r_4> >
380	#pragma define_template LapackServer< complex<r_8> >
381	#endif
382
383	#if defined(ANSI_TEMPLATES) \|\| defined(GNU_TEMPLATES)
384	template class LapackServer<r_4>;
385	template class LapackServer<r_8>;
386	template class LapackServer< complex<r_4> >;
387	template class LapackServer< complex<r_8> >;
388	#endif
389
390	#if defined(OS_LINUX)
391	// Pour le link avec f2c sous Linux
392	extern "C" {
393	void MAIN__();
394	}
395
396	void MAIN__()
397	{
398	cerr << "MAIN__() function for linking with libf2c.a " << endl;
399	cerr << " This function should never be called !!! " << endl;
400	throw PError("MAIN__() should not be called - see intflapack.cc");
401	}
402	#endif

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