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source: tags/3.3.1/HeuristicLab.ExtLibs/HeuristicLab.ALGLIB/2.5.0/ALGLIB-2.5.0/safesolve.cs @ 9407

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Last change on this file since 9407 was 3839, checked in by mkommend, 14 years ago
implemented first version of LR (ticket #1012)
File size: 22.8 KB

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1	/*************************************************************************
2	This file is a part of ALGLIB project.
3
4	>>> SOURCE LICENSE >>>
5	This program is free software; you can redistribute it and/or modify
6	it under the terms of the GNU General Public License as published by
7	the Free Software Foundation (www.fsf.org); either version 2 of the
8	License, or (at your option) any later version.
9
10	This program is distributed in the hope that it will be useful,
11	but WITHOUT ANY WARRANTY; without even the implied warranty of
12	MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
13	GNU General Public License for more details.
14
15	A copy of the GNU General Public License is available at
16	http://www.fsf.org/licensing/licenses
17
18	>>> END OF LICENSE >>>
19	*************************************************************************/
20
21	using System;
22
23	namespace alglib
24	{
25	public class safesolve
26	{
27	/*************************************************************************
28	Real implementation of CMatrixScaledTRSafeSolve
29
30	-- ALGLIB routine --
31	21.01.2010
32	Bochkanov Sergey
33	*************************************************************************/
34	public static bool rmatrixscaledtrsafesolve(ref double[,] a,
35	double sa,
36	int n,
37	ref double[] x,
38	bool isupper,
39	int trans,
40	bool isunit,
41	double maxgrowth)
42	{
43	bool result = new bool();
44	double lnmax = 0;
45	double nrmb = 0;
46	double nrmx = 0;
47	int i = 0;
48	AP.Complex alpha = 0;
49	AP.Complex beta = 0;
50	double vr = 0;
51	AP.Complex cx = 0;
52	double[] tmp = new double[0];
53	int i_ = 0;
54
55	System.Diagnostics.Debug.Assert(n>0, "RMatrixTRSafeSolve: incorrect N!");
56	System.Diagnostics.Debug.Assert(trans==0 \| trans==1, "RMatrixTRSafeSolve: incorrect Trans!");
57	result = true;
58	lnmax = Math.Log(AP.Math.MaxRealNumber);
59
60	//
61	// Quick return if possible
62	//
63	if( n<=0 )
64	{
65	return result;
66	}
67
68	//
69	// Load norms: right part and X
70	//
71	nrmb = 0;
72	for(i=0; i<=n-1; i++)
73	{
74	nrmb = Math.Max(nrmb, Math.Abs(x[i]));
75	}
76	nrmx = 0;
77
78	//
79	// Solve
80	//
81	tmp = new double[n];
82	result = true;
83	if( isupper & trans==0 )
84	{
85
86	//
87	// U*x = b
88	//
89	for(i=n-1; i>=0; i--)
90	{
91
92	//
93	// Task is reduced to alpha*x[i] = beta
94	//
95	if( isunit )
96	{
97	alpha = sa;
98	}
99	else
100	{
101	alpha = a[i,i]*sa;
102	}
103	if( i<n-1 )
104	{
105	for(i_=i+1; i_<=n-1;i_++)
106	{
107	tmp[i_] = sa*a[i,i_];
108	}
109	vr = 0.0;
110	for(i_=i+1; i_<=n-1;i_++)
111	{
112	vr += tmp[i_]*x[i_];
113	}
114	beta = x[i]-vr;
115	}
116	else
117	{
118	beta = x[i];
119	}
120
121	//
122	// solve alpha*x[i] = beta
123	//
124	result = cbasicsolveandupdate(alpha, beta, lnmax, nrmb, maxgrowth, ref nrmx, ref cx);
125	if( !result )
126	{
127	return result;
128	}
129	x[i] = cx.x;
130	}
131	return result;
132	}
133	if( !isupper & trans==0 )
134	{
135
136	//
137	// L*x = b
138	//
139	for(i=0; i<=n-1; i++)
140	{
141
142	//
143	// Task is reduced to alpha*x[i] = beta
144	//
145	if( isunit )
146	{
147	alpha = sa;
148	}
149	else
150	{
151	alpha = a[i,i]*sa;
152	}
153	if( i>0 )
154	{
155	for(i_=0; i_<=i-1;i_++)
156	{
157	tmp[i_] = sa*a[i,i_];
158	}
159	vr = 0.0;
160	for(i_=0; i_<=i-1;i_++)
161	{
162	vr += tmp[i_]*x[i_];
163	}
164	beta = x[i]-vr;
165	}
166	else
167	{
168	beta = x[i];
169	}
170
171	//
172	// solve alpha*x[i] = beta
173	//
174	result = cbasicsolveandupdate(alpha, beta, lnmax, nrmb, maxgrowth, ref nrmx, ref cx);
175	if( !result )
176	{
177	return result;
178	}
179	x[i] = cx.x;
180	}
181	return result;
182	}
183	if( isupper & trans==1 )
184	{
185
186	//
187	// U^T*x = b
188	//
189	for(i=0; i<=n-1; i++)
190	{
191
192	//
193	// Task is reduced to alpha*x[i] = beta
194	//
195	if( isunit )
196	{
197	alpha = sa;
198	}
199	else
200	{
201	alpha = a[i,i]*sa;
202	}
203	beta = x[i];
204
205	//
206	// solve alpha*x[i] = beta
207	//
208	result = cbasicsolveandupdate(alpha, beta, lnmax, nrmb, maxgrowth, ref nrmx, ref cx);
209	if( !result )
210	{
211	return result;
212	}
213	x[i] = cx.x;
214
215	//
216	// update the rest of right part
217	//
218	if( i<n-1 )
219	{
220	vr = cx.x;
221	for(i_=i+1; i_<=n-1;i_++)
222	{
223	tmp[i_] = sa*a[i,i_];
224	}
225	for(i_=i+1; i_<=n-1;i_++)
226	{
227	x[i_] = x[i_] - vr*tmp[i_];
228	}
229	}
230	}
231	return result;
232	}
233	if( !isupper & trans==1 )
234	{
235
236	//
237	// L^T*x = b
238	//
239	for(i=n-1; i>=0; i--)
240	{
241
242	//
243	// Task is reduced to alpha*x[i] = beta
244	//
245	if( isunit )
246	{
247	alpha = sa;
248	}
249	else
250	{
251	alpha = a[i,i]*sa;
252	}
253	beta = x[i];
254
255	//
256	// solve alpha*x[i] = beta
257	//
258	result = cbasicsolveandupdate(alpha, beta, lnmax, nrmb, maxgrowth, ref nrmx, ref cx);
259	if( !result )
260	{
261	return result;
262	}
263	x[i] = cx.x;
264
265	//
266	// update the rest of right part
267	//
268	if( i>0 )
269	{
270	vr = cx.x;
271	for(i_=0; i_<=i-1;i_++)
272	{
273	tmp[i_] = sa*a[i,i_];
274	}
275	for(i_=0; i_<=i-1;i_++)
276	{
277	x[i_] = x[i_] - vr*tmp[i_];
278	}
279	}
280	}
281	return result;
282	}
283	result = false;
284	return result;
285	}
286
287
288	/*************************************************************************
289	Internal subroutine for safe solution of
290
291	SA*op(A)=b
292
293	where A is NxN upper/lower triangular/unitriangular matrix, op(A) is
294	either identity transform, transposition or Hermitian transposition, SA is
295	a scaling factor such that max(\|SA*A[i,j]\|) is close to 1.0 in magnutude.
296
297	This subroutine limits relative growth of solution (in inf-norm) by
298	MaxGrowth, returning False if growth exceeds MaxGrowth. Degenerate or
299	near-degenerate matrices are handled correctly (False is returned) as long
300	as MaxGrowth is significantly less than MaxRealNumber/norm(b).
301
302	-- ALGLIB routine --
303	21.01.2010
304	Bochkanov Sergey
305	*************************************************************************/
306	public static bool cmatrixscaledtrsafesolve(ref AP.Complex[,] a,
307	double sa,
308	int n,
309	ref AP.Complex[] x,
310	bool isupper,
311	int trans,
312	bool isunit,
313	double maxgrowth)
314	{
315	bool result = new bool();
316	double lnmax = 0;
317	double nrmb = 0;
318	double nrmx = 0;
319	int i = 0;
320	AP.Complex alpha = 0;
321	AP.Complex beta = 0;
322	AP.Complex vc = 0;
323	AP.Complex[] tmp = new AP.Complex[0];
324	int i_ = 0;
325
326	System.Diagnostics.Debug.Assert(n>0, "CMatrixTRSafeSolve: incorrect N!");
327	System.Diagnostics.Debug.Assert(trans==0 \| trans==1 \| trans==2, "CMatrixTRSafeSolve: incorrect Trans!");
328	result = true;
329	lnmax = Math.Log(AP.Math.MaxRealNumber);
330
331	//
332	// Quick return if possible
333	//
334	if( n<=0 )
335	{
336	return result;
337	}
338
339	//
340	// Load norms: right part and X
341	//
342	nrmb = 0;
343	for(i=0; i<=n-1; i++)
344	{
345	nrmb = Math.Max(nrmb, AP.Math.AbsComplex(x[i]));
346	}
347	nrmx = 0;
348
349	//
350	// Solve
351	//
352	tmp = new AP.Complex[n];
353	result = true;
354	if( isupper & trans==0 )
355	{
356
357	//
358	// U*x = b
359	//
360	for(i=n-1; i>=0; i--)
361	{
362
363	//
364	// Task is reduced to alpha*x[i] = beta
365	//
366	if( isunit )
367	{
368	alpha = sa;
369	}
370	else
371	{
372	alpha = a[i,i]*sa;
373	}
374	if( i<n-1 )
375	{
376	for(i_=i+1; i_<=n-1;i_++)
377	{
378	tmp[i_] = sa*a[i,i_];
379	}
380	vc = 0.0;
381	for(i_=i+1; i_<=n-1;i_++)
382	{
383	vc += tmp[i_]*x[i_];
384	}
385	beta = x[i]-vc;
386	}
387	else
388	{
389	beta = x[i];
390	}
391
392	//
393	// solve alpha*x[i] = beta
394	//
395	result = cbasicsolveandupdate(alpha, beta, lnmax, nrmb, maxgrowth, ref nrmx, ref vc);
396	if( !result )
397	{
398	return result;
399	}
400	x[i] = vc;
401	}
402	return result;
403	}
404	if( !isupper & trans==0 )
405	{
406
407	//
408	// L*x = b
409	//
410	for(i=0; i<=n-1; i++)
411	{
412
413	//
414	// Task is reduced to alpha*x[i] = beta
415	//
416	if( isunit )
417	{
418	alpha = sa;
419	}
420	else
421	{
422	alpha = a[i,i]*sa;
423	}
424	if( i>0 )
425	{
426	for(i_=0; i_<=i-1;i_++)
427	{
428	tmp[i_] = sa*a[i,i_];
429	}
430	vc = 0.0;
431	for(i_=0; i_<=i-1;i_++)
432	{
433	vc += tmp[i_]*x[i_];
434	}
435	beta = x[i]-vc;
436	}
437	else
438	{
439	beta = x[i];
440	}
441
442	//
443	// solve alpha*x[i] = beta
444	//
445	result = cbasicsolveandupdate(alpha, beta, lnmax, nrmb, maxgrowth, ref nrmx, ref vc);
446	if( !result )
447	{
448	return result;
449	}
450	x[i] = vc;
451	}
452	return result;
453	}
454	if( isupper & trans==1 )
455	{
456
457	//
458	// U^T*x = b
459	//
460	for(i=0; i<=n-1; i++)
461	{
462
463	//
464	// Task is reduced to alpha*x[i] = beta
465	//
466	if( isunit )
467	{
468	alpha = sa;
469	}
470	else
471	{
472	alpha = a[i,i]*sa;
473	}
474	beta = x[i];
475
476	//
477	// solve alpha*x[i] = beta
478	//
479	result = cbasicsolveandupdate(alpha, beta, lnmax, nrmb, maxgrowth, ref nrmx, ref vc);
480	if( !result )
481	{
482	return result;
483	}
484	x[i] = vc;
485
486	//
487	// update the rest of right part
488	//
489	if( i<n-1 )
490	{
491	for(i_=i+1; i_<=n-1;i_++)
492	{
493	tmp[i_] = sa*a[i,i_];
494	}
495	for(i_=i+1; i_<=n-1;i_++)
496	{
497	x[i_] = x[i_] - vc*tmp[i_];
498	}
499	}
500	}
501	return result;
502	}
503	if( !isupper & trans==1 )
504	{
505
506	//
507	// L^T*x = b
508	//
509	for(i=n-1; i>=0; i--)
510	{
511
512	//
513	// Task is reduced to alpha*x[i] = beta
514	//
515	if( isunit )
516	{
517	alpha = sa;
518	}
519	else
520	{
521	alpha = a[i,i]*sa;
522	}
523	beta = x[i];
524
525	//
526	// solve alpha*x[i] = beta
527	//
528	result = cbasicsolveandupdate(alpha, beta, lnmax, nrmb, maxgrowth, ref nrmx, ref vc);
529	if( !result )
530	{
531	return result;
532	}
533	x[i] = vc;
534
535	//
536	// update the rest of right part
537	//
538	if( i>0 )
539	{
540	for(i_=0; i_<=i-1;i_++)
541	{
542	tmp[i_] = sa*a[i,i_];
543	}
544	for(i_=0; i_<=i-1;i_++)
545	{
546	x[i_] = x[i_] - vc*tmp[i_];
547	}
548	}
549	}
550	return result;
551	}
552	if( isupper & trans==2 )
553	{
554
555	//
556	// U^H*x = b
557	//
558	for(i=0; i<=n-1; i++)
559	{
560
561	//
562	// Task is reduced to alpha*x[i] = beta
563	//
564	if( isunit )
565	{
566	alpha = sa;
567	}
568	else
569	{
570	alpha = AP.Math.Conj(a[i,i])*sa;
571	}
572	beta = x[i];
573
574	//
575	// solve alpha*x[i] = beta
576	//
577	result = cbasicsolveandupdate(alpha, beta, lnmax, nrmb, maxgrowth, ref nrmx, ref vc);
578	if( !result )
579	{
580	return result;
581	}
582	x[i] = vc;
583
584	//
585	// update the rest of right part
586	//
587	if( i<n-1 )
588	{
589	for(i_=i+1; i_<=n-1;i_++)
590	{
591	tmp[i_] = sa*AP.Math.Conj(a[i,i_]);
592	}
593	for(i_=i+1; i_<=n-1;i_++)
594	{
595	x[i_] = x[i_] - vc*tmp[i_];
596	}
597	}
598	}
599	return result;
600	}
601	if( !isupper & trans==2 )
602	{
603
604	//
605	// L^T*x = b
606	//
607	for(i=n-1; i>=0; i--)
608	{
609
610	//
611	// Task is reduced to alpha*x[i] = beta
612	//
613	if( isunit )
614	{
615	alpha = sa;
616	}
617	else
618	{
619	alpha = AP.Math.Conj(a[i,i])*sa;
620	}
621	beta = x[i];
622
623	//
624	// solve alpha*x[i] = beta
625	//
626	result = cbasicsolveandupdate(alpha, beta, lnmax, nrmb, maxgrowth, ref nrmx, ref vc);
627	if( !result )
628	{
629	return result;
630	}
631	x[i] = vc;
632
633	//
634	// update the rest of right part
635	//
636	if( i>0 )
637	{
638	for(i_=0; i_<=i-1;i_++)
639	{
640	tmp[i_] = sa*AP.Math.Conj(a[i,i_]);
641	}
642	for(i_=0; i_<=i-1;i_++)
643	{
644	x[i_] = x[i_] - vc*tmp[i_];
645	}
646	}
647	}
648	return result;
649	}
650	result = false;
651	return result;
652	}
653
654
655	/*************************************************************************
656	complex basic solver-updater for reduced linear system
657
658	alpha*x[i] = beta
659
660	solves this equation and updates it in overlfow-safe manner (keeping track
661	of relative growth of solution).
662
663	Parameters:
664	Alpha - alpha
665	Beta - beta
666	LnMax - precomputed Ln(MaxRealNumber)
667	BNorm - inf-norm of b (right part of original system)
668	MaxGrowth- maximum growth of norm(x) relative to norm(b)
669	XNorm - inf-norm of other components of X (which are already processed)
670	it is updated by CBasicSolveAndUpdate.
671	X - solution
672
673	-- ALGLIB routine --
674	26.01.2009
675	Bochkanov Sergey
676	*************************************************************************/
677	private static bool cbasicsolveandupdate(AP.Complex alpha,
678	AP.Complex beta,
679	double lnmax,
680	double bnorm,
681	double maxgrowth,
682	ref double xnorm,
683	ref AP.Complex x)
684	{
685	bool result = new bool();
686	double v = 0;
687
688	result = false;
689	if( alpha==0 )
690	{
691	return result;
692	}
693	if( beta!=0 )
694	{
695
696	//
697	// alpha*x[i]=beta
698	//
699	v = Math.Log(AP.Math.AbsComplex(beta))-Math.Log(AP.Math.AbsComplex(alpha));
700	if( (double)(v)>(double)(lnmax) )
701	{
702	return result;
703	}
704	x = beta/alpha;
705	}
706	else
707	{
708
709	//
710	// alpha*x[i]=0
711	//
712	x = 0;
713	}
714
715	//
716	// update NrmX, test growth limit
717	//
718	xnorm = Math.Max(xnorm, AP.Math.AbsComplex(x));
719	if( (double)(xnorm)>(double)(maxgrowth*bnorm) )
720	{
721	return result;
722	}
723	result = true;
724	return result;
725	}
726	}
727	}

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