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source: tags/3.3.8/HeuristicLab.ExtLibs/HeuristicLab.ALGLIB/3.7.0/ALGLIB-3.7.0/diffequations.cs @ 13398

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Last change on this file since 13398 was 9268, checked in by mkommend, 11 years ago
#2007: Added AlgLib 3.7.0 to the external libraries.
File size: 34.6 KB

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1	/*************************************************************************
2	Copyright (c) Sergey Bochkanov (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	>>> END OF LICENSE >>>
18	*************************************************************************/
19	#pragma warning disable 162
20	#pragma warning disable 219
21	using System;
22
23	public partial class alglib
24	{
25
26
27	/*************************************************************************
28
29	*************************************************************************/
30	public class odesolverstate
31	{
32	//
33	// Public declarations
34	//
35	public bool needdy { get { return _innerobj.needdy; } set { _innerobj.needdy = value; } }
36	public double[] y { get { return _innerobj.y; } }
37	public double[] dy { get { return _innerobj.dy; } }
38	public double x { get { return _innerobj.x; } set { _innerobj.x = value; } }
39
40	public odesolverstate()
41	{
42	_innerobj = new odesolver.odesolverstate();
43	}
44
45	//
46	// Although some of declarations below are public, you should not use them
47	// They are intended for internal use only
48	//
49	private odesolver.odesolverstate _innerobj;
50	public odesolver.odesolverstate innerobj { get { return _innerobj; } }
51	public odesolverstate(odesolver.odesolverstate obj)
52	{
53	_innerobj = obj;
54	}
55	}
56
57
58	/*************************************************************************
59
60	*************************************************************************/
61	public class odesolverreport
62	{
63	//
64	// Public declarations
65	//
66	public int nfev { get { return _innerobj.nfev; } set { _innerobj.nfev = value; } }
67	public int terminationtype { get { return _innerobj.terminationtype; } set { _innerobj.terminationtype = value; } }
68
69	public odesolverreport()
70	{
71	_innerobj = new odesolver.odesolverreport();
72	}
73
74	//
75	// Although some of declarations below are public, you should not use them
76	// They are intended for internal use only
77	//
78	private odesolver.odesolverreport _innerobj;
79	public odesolver.odesolverreport innerobj { get { return _innerobj; } }
80	public odesolverreport(odesolver.odesolverreport obj)
81	{
82	_innerobj = obj;
83	}
84	}
85
86	/*************************************************************************
87	Cash-Karp adaptive ODE solver.
88
89	This subroutine solves ODE Y'=f(Y,x) with initial conditions Y(xs)=Ys
90	(here Y may be single variable or vector of N variables).
91
92	INPUT PARAMETERS:
93	Y - initial conditions, array[0..N-1].
94	contains values of Y[] at X[0]
95	N - system size
96	X - points at which Y should be tabulated, array[0..M-1]
97	integrations starts at X[0], ends at X[M-1], intermediate
98	values at X[i] are returned too.
99	SHOULD BE ORDERED BY ASCENDING OR BY DESCENDING!!!!
100	M - number of intermediate points + first point + last point:
101	* M>2 means that you need both Y(X[M-1]) and M-2 values at
102	intermediate points
103	* M=2 means that you want just to integrate from X[0] to
104	X[1] and don't interested in intermediate values.
105	* M=1 means that you don't want to integrate :)
106	it is degenerate case, but it will be handled correctly.
107	* M<1 means error
108	Eps - tolerance (absolute/relative error on each step will be
109	less than Eps). When passing:
110	* Eps>0, it means desired ABSOLUTE error
111	* Eps<0, it means desired RELATIVE error. Relative errors
112	are calculated with respect to maximum values of Y seen
113	so far. Be careful to use this criterion when starting
114	from Y[] that are close to zero.
115	H - initial step lenth, it will be adjusted automatically
116	after the first step. If H=0, step will be selected
117	automatically (usualy it will be equal to 0.001 of
118	min(x[i]-x[j])).
119
120	OUTPUT PARAMETERS
121	State - structure which stores algorithm state between subsequent
122	calls of OdeSolverIteration. Used for reverse communication.
123	This structure should be passed to the OdeSolverIteration
124	subroutine.
125
126	SEE ALSO
127	AutoGKSmoothW, AutoGKSingular, AutoGKIteration, AutoGKResults.
128
129
130	-- ALGLIB --
131	Copyright 01.09.2009 by Bochkanov Sergey
132	*************************************************************************/
133	public static void odesolverrkck(double[] y, int n, double[] x, int m, double eps, double h, out odesolverstate state)
134	{
135	state = new odesolverstate();
136	odesolver.odesolverrkck(y, n, x, m, eps, h, state.innerobj);
137	return;
138	}
139	public static void odesolverrkck(double[] y, double[] x, double eps, double h, out odesolverstate state)
140	{
141	int n;
142	int m;
143
144	state = new odesolverstate();
145	n = ap.len(y);
146	m = ap.len(x);
147	odesolver.odesolverrkck(y, n, x, m, eps, h, state.innerobj);
148
149	return;
150	}
151
152	/*************************************************************************
153	This function provides reverse communication interface
154	Reverse communication interface is not documented or recommended to use.
155	See below for functions which provide better documented API
156	*************************************************************************/
157	public static bool odesolveriteration(odesolverstate state)
158	{
159
160	bool result = odesolver.odesolveriteration(state.innerobj);
161	return result;
162	}
163	/*************************************************************************
164	This function is used to launcn iterations of ODE solver
165
166	It accepts following parameters:
167	diff - callback which calculates dy/dx for given y and x
168	obj - optional object which is passed to diff; can be NULL
169
170
171	-- ALGLIB --
172	Copyright 01.09.2009 by Bochkanov Sergey
173
174	*************************************************************************/
175	public static void odesolversolve(odesolverstate state, ndimensional_ode_rp diff, object obj)
176	{
177	if( diff==null )
178	throw new alglibexception("ALGLIB: error in 'odesolversolve()' (diff is null)");
179	while( alglib.odesolveriteration(state) )
180	{
181	if( state.needdy )
182	{
183	diff(state.innerobj.y, state.innerobj.x, state.innerobj.dy, obj);
184	continue;
185	}
186	throw new alglibexception("ALGLIB: unexpected error in 'odesolversolve'");
187	}
188	}
189
190
191
192	/*************************************************************************
193	ODE solver results
194
195	Called after OdeSolverIteration returned False.
196
197	INPUT PARAMETERS:
198	State - algorithm state (used by OdeSolverIteration).
199
200	OUTPUT PARAMETERS:
201	M - number of tabulated values, M>=1
202	XTbl - array[0..M-1], values of X
203	YTbl - array[0..M-1,0..N-1], values of Y in X[i]
204	Rep - solver report:
205	* Rep.TerminationType completetion code:
206	* -2 X is not ordered by ascending/descending or
207	there are non-distinct X[], i.e. X[i]=X[i+1]
208	* -1 incorrect parameters were specified
209	* 1 task has been solved
210	* Rep.NFEV contains number of function calculations
211
212	-- ALGLIB --
213	Copyright 01.09.2009 by Bochkanov Sergey
214	*************************************************************************/
215	public static void odesolverresults(odesolverstate state, out int m, out double[] xtbl, out double[,] ytbl, out odesolverreport rep)
216	{
217	m = 0;
218	xtbl = new double[0];
219	ytbl = new double[0,0];
220	rep = new odesolverreport();
221	odesolver.odesolverresults(state.innerobj, ref m, ref xtbl, ref ytbl, rep.innerobj);
222	return;
223	}
224
225	}
226	public partial class alglib
227	{
228	public class odesolver
229	{
230	public class odesolverstate : apobject
231	{
232	public int n;
233	public int m;
234	public double xscale;
235	public double h;
236	public double eps;
237	public bool fraceps;
238	public double[] yc;
239	public double[] escale;
240	public double[] xg;
241	public int solvertype;
242	public bool needdy;
243	public double x;
244	public double[] y;
245	public double[] dy;
246	public double[,] ytbl;
247	public int repterminationtype;
248	public int repnfev;
249	public double[] yn;
250	public double[] yns;
251	public double[] rka;
252	public double[] rkc;
253	public double[] rkcs;
254	public double[,] rkb;
255	public double[,] rkk;
256	public rcommstate rstate;
257	public odesolverstate()
258	{
259	init();
260	}
261	public override void init()
262	{
263	yc = new double[0];
264	escale = new double[0];
265	xg = new double[0];
266	y = new double[0];
267	dy = new double[0];
268	ytbl = new double[0,0];
269	yn = new double[0];
270	yns = new double[0];
271	rka = new double[0];
272	rkc = new double[0];
273	rkcs = new double[0];
274	rkb = new double[0,0];
275	rkk = new double[0,0];
276	rstate = new rcommstate();
277	}
278	public override alglib.apobject make_copy()
279	{
280	odesolverstate _result = new odesolverstate();
281	_result.n = n;
282	_result.m = m;
283	_result.xscale = xscale;
284	_result.h = h;
285	_result.eps = eps;
286	_result.fraceps = fraceps;
287	_result.yc = (double[])yc.Clone();
288	_result.escale = (double[])escale.Clone();
289	_result.xg = (double[])xg.Clone();
290	_result.solvertype = solvertype;
291	_result.needdy = needdy;
292	_result.x = x;
293	_result.y = (double[])y.Clone();
294	_result.dy = (double[])dy.Clone();
295	_result.ytbl = (double[,])ytbl.Clone();
296	_result.repterminationtype = repterminationtype;
297	_result.repnfev = repnfev;
298	_result.yn = (double[])yn.Clone();
299	_result.yns = (double[])yns.Clone();
300	_result.rka = (double[])rka.Clone();
301	_result.rkc = (double[])rkc.Clone();
302	_result.rkcs = (double[])rkcs.Clone();
303	_result.rkb = (double[,])rkb.Clone();
304	_result.rkk = (double[,])rkk.Clone();
305	_result.rstate = (rcommstate)rstate.make_copy();
306	return _result;
307	}
308	};
309
310
311	public class odesolverreport : apobject
312	{
313	public int nfev;
314	public int terminationtype;
315	public odesolverreport()
316	{
317	init();
318	}
319	public override void init()
320	{
321	}
322	public override alglib.apobject make_copy()
323	{
324	odesolverreport _result = new odesolverreport();
325	_result.nfev = nfev;
326	_result.terminationtype = terminationtype;
327	return _result;
328	}
329	};
330
331
332
333
334	public const double odesolvermaxgrow = 3.0;
335	public const double odesolvermaxshrink = 10.0;
336
337
338	/*************************************************************************
339	Cash-Karp adaptive ODE solver.
340
341	This subroutine solves ODE Y'=f(Y,x) with initial conditions Y(xs)=Ys
342	(here Y may be single variable or vector of N variables).
343
344	INPUT PARAMETERS:
345	Y - initial conditions, array[0..N-1].
346	contains values of Y[] at X[0]
347	N - system size
348	X - points at which Y should be tabulated, array[0..M-1]
349	integrations starts at X[0], ends at X[M-1], intermediate
350	values at X[i] are returned too.
351	SHOULD BE ORDERED BY ASCENDING OR BY DESCENDING!!!!
352	M - number of intermediate points + first point + last point:
353	* M>2 means that you need both Y(X[M-1]) and M-2 values at
354	intermediate points
355	* M=2 means that you want just to integrate from X[0] to
356	X[1] and don't interested in intermediate values.
357	* M=1 means that you don't want to integrate :)
358	it is degenerate case, but it will be handled correctly.
359	* M<1 means error
360	Eps - tolerance (absolute/relative error on each step will be
361	less than Eps). When passing:
362	* Eps>0, it means desired ABSOLUTE error
363	* Eps<0, it means desired RELATIVE error. Relative errors
364	are calculated with respect to maximum values of Y seen
365	so far. Be careful to use this criterion when starting
366	from Y[] that are close to zero.
367	H - initial step lenth, it will be adjusted automatically
368	after the first step. If H=0, step will be selected
369	automatically (usualy it will be equal to 0.001 of
370	min(x[i]-x[j])).
371
372	OUTPUT PARAMETERS
373	State - structure which stores algorithm state between subsequent
374	calls of OdeSolverIteration. Used for reverse communication.
375	This structure should be passed to the OdeSolverIteration
376	subroutine.
377
378	SEE ALSO
379	AutoGKSmoothW, AutoGKSingular, AutoGKIteration, AutoGKResults.
380
381
382	-- ALGLIB --
383	Copyright 01.09.2009 by Bochkanov Sergey
384	*************************************************************************/
385	public static void odesolverrkck(double[] y,
386	int n,
387	double[] x,
388	int m,
389	double eps,
390	double h,
391	odesolverstate state)
392	{
393	alglib.ap.assert(n>=1, "ODESolverRKCK: N<1!");
394	alglib.ap.assert(m>=1, "ODESolverRKCK: M<1!");
395	alglib.ap.assert(alglib.ap.len(y)>=n, "ODESolverRKCK: Length(Y)<N!");
396	alglib.ap.assert(alglib.ap.len(x)>=m, "ODESolverRKCK: Length(X)<M!");
397	alglib.ap.assert(apserv.isfinitevector(y, n), "ODESolverRKCK: Y contains infinite or NaN values!");
398	alglib.ap.assert(apserv.isfinitevector(x, m), "ODESolverRKCK: Y contains infinite or NaN values!");
399	alglib.ap.assert(math.isfinite(eps), "ODESolverRKCK: Eps is not finite!");
400	alglib.ap.assert((double)(eps)!=(double)(0), "ODESolverRKCK: Eps is zero!");
401	alglib.ap.assert(math.isfinite(h), "ODESolverRKCK: H is not finite!");
402	odesolverinit(0, y, n, x, m, eps, h, state);
403	}
404
405
406	/*************************************************************************
407
408	-- ALGLIB --
409	Copyright 01.09.2009 by Bochkanov Sergey
410	*************************************************************************/
411	public static bool odesolveriteration(odesolverstate state)
412	{
413	bool result = new bool();
414	int n = 0;
415	int m = 0;
416	int i = 0;
417	int j = 0;
418	int k = 0;
419	double xc = 0;
420	double v = 0;
421	double h = 0;
422	double h2 = 0;
423	bool gridpoint = new bool();
424	double err = 0;
425	double maxgrowpow = 0;
426	int klimit = 0;
427	int i_ = 0;
428
429
430	//
431	// Reverse communication preparations
432	// I know it looks ugly, but it works the same way
433	// anywhere from C++ to Python.
434	//
435	// This code initializes locals by:
436	// * random values determined during code
437	// generation - on first subroutine call
438	// * values from previous call - on subsequent calls
439	//
440	if( state.rstate.stage>=0 )
441	{
442	n = state.rstate.ia[0];
443	m = state.rstate.ia[1];
444	i = state.rstate.ia[2];
445	j = state.rstate.ia[3];
446	k = state.rstate.ia[4];
447	klimit = state.rstate.ia[5];
448	gridpoint = state.rstate.ba[0];
449	xc = state.rstate.ra[0];
450	v = state.rstate.ra[1];
451	h = state.rstate.ra[2];
452	h2 = state.rstate.ra[3];
453	err = state.rstate.ra[4];
454	maxgrowpow = state.rstate.ra[5];
455	}
456	else
457	{
458	n = -983;
459	m = -989;
460	i = -834;
461	j = 900;
462	k = -287;
463	klimit = 364;
464	gridpoint = false;
465	xc = -338;
466	v = -686;
467	h = 912;
468	h2 = 585;
469	err = 497;
470	maxgrowpow = -271;
471	}
472	if( state.rstate.stage==0 )
473	{
474	goto lbl_0;
475	}
476
477	//
478	// Routine body
479	//
480
481	//
482	// prepare
483	//
484	if( state.repterminationtype!=0 )
485	{
486	result = false;
487	return result;
488	}
489	n = state.n;
490	m = state.m;
491	h = state.h;
492	maxgrowpow = Math.Pow(odesolvermaxgrow, 5);
493	state.repnfev = 0;
494
495	//
496	// some preliminary checks for internal errors
497	// after this we assume that H>0 and M>1
498	//
499	alglib.ap.assert((double)(state.h)>(double)(0), "ODESolver: internal error");
500	alglib.ap.assert(m>1, "ODESolverIteration: internal error");
501
502	//
503	// choose solver
504	//
505	if( state.solvertype!=0 )
506	{
507	goto lbl_1;
508	}
509
510	//
511	// Cask-Karp solver
512	// Prepare coefficients table.
513	// Check it for errors
514	//
515	state.rka = new double[6];
516	state.rka[0] = 0;
517	state.rka[1] = (double)1/(double)5;
518	state.rka[2] = (double)3/(double)10;
519	state.rka[3] = (double)3/(double)5;
520	state.rka[4] = 1;
521	state.rka[5] = (double)7/(double)8;
522	state.rkb = new double[6, 5];
523	state.rkb[1,0] = (double)1/(double)5;
524	state.rkb[2,0] = (double)3/(double)40;
525	state.rkb[2,1] = (double)9/(double)40;
526	state.rkb[3,0] = (double)3/(double)10;
527	state.rkb[3,1] = -((double)9/(double)10);
528	state.rkb[3,2] = (double)6/(double)5;
529	state.rkb[4,0] = -((double)11/(double)54);
530	state.rkb[4,1] = (double)5/(double)2;
531	state.rkb[4,2] = -((double)70/(double)27);
532	state.rkb[4,3] = (double)35/(double)27;
533	state.rkb[5,0] = (double)1631/(double)55296;
534	state.rkb[5,1] = (double)175/(double)512;
535	state.rkb[5,2] = (double)575/(double)13824;
536	state.rkb[5,3] = (double)44275/(double)110592;
537	state.rkb[5,4] = (double)253/(double)4096;
538	state.rkc = new double[6];
539	state.rkc[0] = (double)37/(double)378;
540	state.rkc[1] = 0;
541	state.rkc[2] = (double)250/(double)621;
542	state.rkc[3] = (double)125/(double)594;
543	state.rkc[4] = 0;
544	state.rkc[5] = (double)512/(double)1771;
545	state.rkcs = new double[6];
546	state.rkcs[0] = (double)2825/(double)27648;
547	state.rkcs[1] = 0;
548	state.rkcs[2] = (double)18575/(double)48384;
549	state.rkcs[3] = (double)13525/(double)55296;
550	state.rkcs[4] = (double)277/(double)14336;
551	state.rkcs[5] = (double)1/(double)4;
552	state.rkk = new double[6, n];
553
554	//
555	// Main cycle consists of two iterations:
556	// * outer where we travel from X[i-1] to X[i]
557	// * inner where we travel inside [X[i-1],X[i]]
558	//
559	state.ytbl = new double[m, n];
560	state.escale = new double[n];
561	state.yn = new double[n];
562	state.yns = new double[n];
563	xc = state.xg[0];
564	for(i_=0; i_<=n-1;i_++)
565	{
566	state.ytbl[0,i_] = state.yc[i_];
567	}
568	for(j=0; j<=n-1; j++)
569	{
570	state.escale[j] = 0;
571	}
572	i = 1;
573	lbl_3:
574	if( i>m-1 )
575	{
576	goto lbl_5;
577	}
578
579	//
580	// begin inner iteration
581	//
582	lbl_6:
583	if( false )
584	{
585	goto lbl_7;
586	}
587
588	//
589	// truncate step if needed (beyond right boundary).
590	// determine should we store X or not
591	//
592	if( (double)(xc+h)>=(double)(state.xg[i]) )
593	{
594	h = state.xg[i]-xc;
595	gridpoint = true;
596	}
597	else
598	{
599	gridpoint = false;
600	}
601
602	//
603	// Update error scale maximums
604	//
605	// These maximums are initialized by zeros,
606	// then updated every iterations.
607	//
608	for(j=0; j<=n-1; j++)
609	{
610	state.escale[j] = Math.Max(state.escale[j], Math.Abs(state.yc[j]));
611	}
612
613	//
614	// make one step:
615	// 1. calculate all info needed to do step
616	// 2. update errors scale maximums using values/derivatives
617	// obtained during (1)
618	//
619	// Take into account that we use scaling of X to reduce task
620	// to the form where x[0] < x[1] < ... < x[n-1]. So X is
621	// replaced by x=xscale*t, and dy/dx=f(y,x) is replaced
622	// by dy/dt=xscalef(y,xscalet).
623	//
624	for(i_=0; i_<=n-1;i_++)
625	{
626	state.yn[i_] = state.yc[i_];
627	}
628	for(i_=0; i_<=n-1;i_++)
629	{
630	state.yns[i_] = state.yc[i_];
631	}
632	k = 0;
633	lbl_8:
634	if( k>5 )
635	{
636	goto lbl_10;
637	}
638
639	//
640	// prepare data for the next update of YN/YNS
641	//
642	state.x = state.xscale(xc+state.rka[k]h);
643	for(i_=0; i_<=n-1;i_++)
644	{
645	state.y[i_] = state.yc[i_];
646	}
647	for(j=0; j<=k-1; j++)
648	{
649	v = state.rkb[k,j];
650	for(i_=0; i_<=n-1;i_++)
651	{
652	state.y[i_] = state.y[i_] + v*state.rkk[j,i_];
653	}
654	}
655	state.needdy = true;
656	state.rstate.stage = 0;
657	goto lbl_rcomm;
658	lbl_0:
659	state.needdy = false;
660	state.repnfev = state.repnfev+1;
661	v = h*state.xscale;
662	for(i_=0; i_<=n-1;i_++)
663	{
664	state.rkk[k,i_] = v*state.dy[i_];
665	}
666
667	//
668	// update YN/YNS
669	//
670	v = state.rkc[k];
671	for(i_=0; i_<=n-1;i_++)
672	{
673	state.yn[i_] = state.yn[i_] + v*state.rkk[k,i_];
674	}
675	v = state.rkcs[k];
676	for(i_=0; i_<=n-1;i_++)
677	{
678	state.yns[i_] = state.yns[i_] + v*state.rkk[k,i_];
679	}
680	k = k+1;
681	goto lbl_8;
682	lbl_10:
683
684	//
685	// estimate error
686	//
687	err = 0;
688	for(j=0; j<=n-1; j++)
689	{
690	if( !state.fraceps )
691	{
692
693	//
694	// absolute error is estimated
695	//
696	err = Math.Max(err, Math.Abs(state.yn[j]-state.yns[j]));
697	}
698	else
699	{
700
701	//
702	// Relative error is estimated
703	//
704	v = state.escale[j];
705	if( (double)(v)==(double)(0) )
706	{
707	v = 1;
708	}
709	err = Math.Max(err, Math.Abs(state.yn[j]-state.yns[j])/v);
710	}
711	}
712
713	//
714	// calculate new step, restart if necessary
715	//
716	if( (double)(maxgrowpow*err)<=(double)(state.eps) )
717	{
718	h2 = odesolvermaxgrow*h;
719	}
720	else
721	{
722	h2 = h*Math.Pow(state.eps/err, 0.2);
723	}
724	if( (double)(h2)<(double)(h/odesolvermaxshrink) )
725	{
726	h2 = h/odesolvermaxshrink;
727	}
728	if( (double)(err)>(double)(state.eps) )
729	{
730	h = h2;
731	goto lbl_6;
732	}
733
734	//
735	// advance position
736	//
737	xc = xc+h;
738	for(i_=0; i_<=n-1;i_++)
739	{
740	state.yc[i_] = state.yn[i_];
741	}
742
743	//
744	// update H
745	//
746	h = h2;
747
748	//
749	// break on grid point
750	//
751	if( gridpoint )
752	{
753	goto lbl_7;
754	}
755	goto lbl_6;
756	lbl_7:
757
758	//
759	// save result
760	//
761	for(i_=0; i_<=n-1;i_++)
762	{
763	state.ytbl[i,i_] = state.yc[i_];
764	}
765	i = i+1;
766	goto lbl_3;
767	lbl_5:
768	state.repterminationtype = 1;
769	result = false;
770	return result;
771	lbl_1:
772	result = false;
773	return result;
774
775	//
776	// Saving state
777	//
778	lbl_rcomm:
779	result = true;
780	state.rstate.ia[0] = n;
781	state.rstate.ia[1] = m;
782	state.rstate.ia[2] = i;
783	state.rstate.ia[3] = j;
784	state.rstate.ia[4] = k;
785	state.rstate.ia[5] = klimit;
786	state.rstate.ba[0] = gridpoint;
787	state.rstate.ra[0] = xc;
788	state.rstate.ra[1] = v;
789	state.rstate.ra[2] = h;
790	state.rstate.ra[3] = h2;
791	state.rstate.ra[4] = err;
792	state.rstate.ra[5] = maxgrowpow;
793	return result;
794	}
795
796
797	/*************************************************************************
798	ODE solver results
799
800	Called after OdeSolverIteration returned False.
801
802	INPUT PARAMETERS:
803	State - algorithm state (used by OdeSolverIteration).
804
805	OUTPUT PARAMETERS:
806	M - number of tabulated values, M>=1
807	XTbl - array[0..M-1], values of X
808	YTbl - array[0..M-1,0..N-1], values of Y in X[i]
809	Rep - solver report:
810	* Rep.TerminationType completetion code:
811	* -2 X is not ordered by ascending/descending or
812	there are non-distinct X[], i.e. X[i]=X[i+1]
813	* -1 incorrect parameters were specified
814	* 1 task has been solved
815	* Rep.NFEV contains number of function calculations
816
817	-- ALGLIB --
818	Copyright 01.09.2009 by Bochkanov Sergey
819	*************************************************************************/
820	public static void odesolverresults(odesolverstate state,
821	ref int m,
822	ref double[] xtbl,
823	ref double[,] ytbl,
824	odesolverreport rep)
825	{
826	double v = 0;
827	int i = 0;
828	int i_ = 0;
829
830	m = 0;
831	xtbl = new double[0];
832	ytbl = new double[0,0];
833
834	rep.terminationtype = state.repterminationtype;
835	if( rep.terminationtype>0 )
836	{
837	m = state.m;
838	rep.nfev = state.repnfev;
839	xtbl = new double[state.m];
840	v = state.xscale;
841	for(i_=0; i_<=state.m-1;i_++)
842	{
843	xtbl[i_] = v*state.xg[i_];
844	}
845	ytbl = new double[state.m, state.n];
846	for(i=0; i<=state.m-1; i++)
847	{
848	for(i_=0; i_<=state.n-1;i_++)
849	{
850	ytbl[i,i_] = state.ytbl[i,i_];
851	}
852	}
853	}
854	else
855	{
856	rep.nfev = 0;
857	}
858	}
859
860
861	/*************************************************************************
862	Internal initialization subroutine
863	*************************************************************************/
864	private static void odesolverinit(int solvertype,
865	double[] y,
866	int n,
867	double[] x,
868	int m,
869	double eps,
870	double h,
871	odesolverstate state)
872	{
873	int i = 0;
874	double v = 0;
875	int i_ = 0;
876
877
878	//
879	// Prepare RComm
880	//
881	state.rstate.ia = new int[5+1];
882	state.rstate.ba = new bool[0+1];
883	state.rstate.ra = new double[5+1];
884	state.rstate.stage = -1;
885	state.needdy = false;
886
887	//
888	// check parameters.
889	//
890	if( (n<=0 \|\| m<1) \|\| (double)(eps)==(double)(0) )
891	{
892	state.repterminationtype = -1;
893	return;
894	}
895	if( (double)(h)<(double)(0) )
896	{
897	h = -h;
898	}
899
900	//
901	// quick exit if necessary.
902	// after this block we assume that M>1
903	//
904	if( m==1 )
905	{
906	state.repnfev = 0;
907	state.repterminationtype = 1;
908	state.ytbl = new double[1, n];
909	for(i_=0; i_<=n-1;i_++)
910	{
911	state.ytbl[0,i_] = y[i_];
912	}
913	state.xg = new double[m];
914	for(i_=0; i_<=m-1;i_++)
915	{
916	state.xg[i_] = x[i_];
917	}
918	return;
919	}
920
921	//
922	// check again: correct order of X[]
923	//
924	if( (double)(x[1])==(double)(x[0]) )
925	{
926	state.repterminationtype = -2;
927	return;
928	}
929	for(i=1; i<=m-1; i++)
930	{
931	if( ((double)(x[1])>(double)(x[0]) && (double)(x[i])<=(double)(x[i-1])) \|\| ((double)(x[1])<(double)(x[0]) && (double)(x[i])>=(double)(x[i-1])) )
932	{
933	state.repterminationtype = -2;
934	return;
935	}
936	}
937
938	//
939	// auto-select H if necessary
940	//
941	if( (double)(h)==(double)(0) )
942	{
943	v = Math.Abs(x[1]-x[0]);
944	for(i=2; i<=m-1; i++)
945	{
946	v = Math.Min(v, Math.Abs(x[i]-x[i-1]));
947	}
948	h = 0.001*v;
949	}
950
951	//
952	// store parameters
953	//
954	state.n = n;
955	state.m = m;
956	state.h = h;
957	state.eps = Math.Abs(eps);
958	state.fraceps = (double)(eps)<(double)(0);
959	state.xg = new double[m];
960	for(i_=0; i_<=m-1;i_++)
961	{
962	state.xg[i_] = x[i_];
963	}
964	if( (double)(x[1])>(double)(x[0]) )
965	{
966	state.xscale = 1;
967	}
968	else
969	{
970	state.xscale = -1;
971	for(i_=0; i_<=m-1;i_++)
972	{
973	state.xg[i_] = -1*state.xg[i_];
974	}
975	}
976	state.yc = new double[n];
977	for(i_=0; i_<=n-1;i_++)
978	{
979	state.yc[i_] = y[i_];
980	}
981	state.solvertype = solvertype;
982	state.repterminationtype = 0;
983
984	//
985	// Allocate arrays
986	//
987	state.y = new double[n];
988	state.dy = new double[n];
989	}
990
991
992	}
993	}
994

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