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source: trunk/HeuristicLab.ExtLibs/HeuristicLab.ALGLIB/3.15.0/ALGLIB-3.15.0/diffequations.cs

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Last change on this file was 16684, checked in by gkronber, 5 years ago
#2435: added 3.15.0 version of alglib as external library (build from source)
File size: 36.7 KB

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1	/*************************************************************************
2	ALGLIB 3.15.0 (source code generated 2019-02-20)
3	Copyright (c) Sergey Bochkanov (ALGLIB project).
4
5	>>> SOURCE LICENSE >>>
6	This program is free software; you can redistribute it and/or modify
7	it under the terms of the GNU General Public License as published by
8	the Free Software Foundation (www.fsf.org); either version 2 of the
9	License, or (at your option) any later version.
10
11	This program is distributed in the hope that it will be useful,
12	but WITHOUT ANY WARRANTY; without even the implied warranty of
13	MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
14	GNU General Public License for more details.
15
16	A copy of the GNU General Public License is available at
17	http://www.fsf.org/licensing/licenses
18	>>> END OF LICENSE >>>
19	*************************************************************************/
20	#pragma warning disable 162
21	#pragma warning disable 164
22	#pragma warning disable 219
23	using System;
24
25	public partial class alglib
26	{
27
28
29	/*************************************************************************
30
31	*************************************************************************/
32	public class odesolverstate : alglibobject
33	{
34	//
35	// Public declarations
36	//
37	public bool needdy { get { return _innerobj.needdy; } set { _innerobj.needdy = value; } }
38	public double[] y { get { return _innerobj.y; } }
39	public double[] dy { get { return _innerobj.dy; } }
40	public double x { get { return _innerobj.x; } set { _innerobj.x = value; } }
41
42	public odesolverstate()
43	{
44	_innerobj = new odesolver.odesolverstate();
45	}
46
47	public override alglib.alglibobject make_copy()
48	{
49	return new odesolverstate((odesolver.odesolverstate)_innerobj.make_copy());
50	}
51
52	//
53	// Although some of declarations below are public, you should not use them
54	// They are intended for internal use only
55	//
56	private odesolver.odesolverstate _innerobj;
57	public odesolver.odesolverstate innerobj { get { return _innerobj; } }
58	public odesolverstate(odesolver.odesolverstate obj)
59	{
60	_innerobj = obj;
61	}
62	}
63
64
65	/*************************************************************************
66
67	*************************************************************************/
68	public class odesolverreport : alglibobject
69	{
70	//
71	// Public declarations
72	//
73	public int nfev { get { return _innerobj.nfev; } set { _innerobj.nfev = value; } }
74	public int terminationtype { get { return _innerobj.terminationtype; } set { _innerobj.terminationtype = value; } }
75
76	public odesolverreport()
77	{
78	_innerobj = new odesolver.odesolverreport();
79	}
80
81	public override alglib.alglibobject make_copy()
82	{
83	return new odesolverreport((odesolver.odesolverreport)_innerobj.make_copy());
84	}
85
86	//
87	// Although some of declarations below are public, you should not use them
88	// They are intended for internal use only
89	//
90	private odesolver.odesolverreport _innerobj;
91	public odesolver.odesolverreport innerobj { get { return _innerobj; } }
92	public odesolverreport(odesolver.odesolverreport obj)
93	{
94	_innerobj = obj;
95	}
96	}
97
98	/*************************************************************************
99	Cash-Karp adaptive ODE solver.
100
101	This subroutine solves ODE Y'=f(Y,x) with initial conditions Y(xs)=Ys
102	(here Y may be single variable or vector of N variables).
103
104	INPUT PARAMETERS:
105	Y - initial conditions, array[0..N-1].
106	contains values of Y[] at X[0]
107	N - system size
108	X - points at which Y should be tabulated, array[0..M-1]
109	integrations starts at X[0], ends at X[M-1], intermediate
110	values at X[i] are returned too.
111	SHOULD BE ORDERED BY ASCENDING OR BY DESCENDING!
112	M - number of intermediate points + first point + last point:
113	* M>2 means that you need both Y(X[M-1]) and M-2 values at
114	intermediate points
115	* M=2 means that you want just to integrate from X[0] to
116	X[1] and don't interested in intermediate values.
117	* M=1 means that you don't want to integrate :)
118	it is degenerate case, but it will be handled correctly.
119	* M<1 means error
120	Eps - tolerance (absolute/relative error on each step will be
121	less than Eps). When passing:
122	* Eps>0, it means desired ABSOLUTE error
123	* Eps<0, it means desired RELATIVE error. Relative errors
124	are calculated with respect to maximum values of Y seen
125	so far. Be careful to use this criterion when starting
126	from Y[] that are close to zero.
127	H - initial step lenth, it will be adjusted automatically
128	after the first step. If H=0, step will be selected
129	automatically (usualy it will be equal to 0.001 of
130	min(x[i]-x[j])).
131
132	OUTPUT PARAMETERS
133	State - structure which stores algorithm state between subsequent
134	calls of OdeSolverIteration. Used for reverse communication.
135	This structure should be passed to the OdeSolverIteration
136	subroutine.
137
138	SEE ALSO
139	AutoGKSmoothW, AutoGKSingular, AutoGKIteration, AutoGKResults.
140
141
142	-- ALGLIB --
143	Copyright 01.09.2009 by Bochkanov Sergey
144	*************************************************************************/
145	public static void odesolverrkck(double[] y, int n, double[] x, int m, double eps, double h, out odesolverstate state)
146	{
147	state = new odesolverstate();
148	odesolver.odesolverrkck(y, n, x, m, eps, h, state.innerobj, null);
149	}
150
151	public static void odesolverrkck(double[] y, int n, double[] x, int m, double eps, double h, out odesolverstate state, alglib.xparams _params)
152	{
153	state = new odesolverstate();
154	odesolver.odesolverrkck(y, n, x, m, eps, h, state.innerobj, _params);
155	}
156
157	public static void odesolverrkck(double[] y, double[] x, double eps, double h, out odesolverstate state)
158	{
159	int n;
160	int m;
161
162	state = new odesolverstate();
163	n = ap.len(y);
164	m = ap.len(x);
165	odesolver.odesolverrkck(y, n, x, m, eps, h, state.innerobj, null);
166
167	return;
168	}
169
170	public static void odesolverrkck(double[] y, double[] x, double eps, double h, out odesolverstate state, alglib.xparams _params)
171	{
172	int n;
173	int m;
174
175	state = new odesolverstate();
176	n = ap.len(y);
177	m = ap.len(x);
178	odesolver.odesolverrkck(y, n, x, m, eps, h, state.innerobj, _params);
179
180	return;
181	}
182
183	/*************************************************************************
184	This function provides reverse communication interface
185	Reverse communication interface is not documented or recommended to use.
186	See below for functions which provide better documented API
187	*************************************************************************/
188	public static bool odesolveriteration(odesolverstate state)
189	{
190
191	return odesolver.odesolveriteration(state.innerobj, null);
192	}
193
194	public static bool odesolveriteration(odesolverstate state, alglib.xparams _params)
195	{
196
197	return odesolver.odesolveriteration(state.innerobj, _params);
198	}
199	/*************************************************************************
200	This function is used to launcn iterations of ODE solver
201
202	It accepts following parameters:
203	diff - callback which calculates dy/dx for given y and x
204	obj - optional object which is passed to diff; can be NULL
205
206
207	-- ALGLIB --
208	Copyright 01.09.2009 by Bochkanov Sergey
209
210	*************************************************************************/
211	public static void odesolversolve(odesolverstate state, ndimensional_ode_rp diff, object obj)
212	{
213	odesolversolve(state, diff, obj, null);
214	}
215
216	public static void odesolversolve(odesolverstate state, ndimensional_ode_rp diff, object obj, alglib.xparams _params)
217	{
218	if( diff==null )
219	throw new alglibexception("ALGLIB: error in 'odesolversolve()' (diff is null)");
220	while( alglib.odesolveriteration(state, _params) )
221	{
222	if( state.needdy )
223	{
224	diff(state.innerobj.y, state.innerobj.x, state.innerobj.dy, obj);
225	continue;
226	}
227	throw new alglibexception("ALGLIB: unexpected error in 'odesolversolve'");
228	}
229	}
230
231
232
233	/*************************************************************************
234	ODE solver results
235
236	Called after OdeSolverIteration returned False.
237
238	INPUT PARAMETERS:
239	State - algorithm state (used by OdeSolverIteration).
240
241	OUTPUT PARAMETERS:
242	M - number of tabulated values, M>=1
243	XTbl - array[0..M-1], values of X
244	YTbl - array[0..M-1,0..N-1], values of Y in X[i]
245	Rep - solver report:
246	* Rep.TerminationType completetion code:
247	* -2 X is not ordered by ascending/descending or
248	there are non-distinct X[], i.e. X[i]=X[i+1]
249	* -1 incorrect parameters were specified
250	* 1 task has been solved
251	* Rep.NFEV contains number of function calculations
252
253	-- ALGLIB --
254	Copyright 01.09.2009 by Bochkanov Sergey
255	*************************************************************************/
256	public static void odesolverresults(odesolverstate state, out int m, out double[] xtbl, out double[,] ytbl, out odesolverreport rep)
257	{
258	m = 0;
259	xtbl = new double[0];
260	ytbl = new double[0,0];
261	rep = new odesolverreport();
262	odesolver.odesolverresults(state.innerobj, ref m, ref xtbl, ref ytbl, rep.innerobj, null);
263	}
264
265	public static void odesolverresults(odesolverstate state, out int m, out double[] xtbl, out double[,] ytbl, out odesolverreport rep, alglib.xparams _params)
266	{
267	m = 0;
268	xtbl = new double[0];
269	ytbl = new double[0,0];
270	rep = new odesolverreport();
271	odesolver.odesolverresults(state.innerobj, ref m, ref xtbl, ref ytbl, rep.innerobj, _params);
272	}
273
274	}
275	public partial class alglib
276	{
277	public class odesolver
278	{
279	public class odesolverstate : apobject
280	{
281	public int n;
282	public int m;
283	public double xscale;
284	public double h;
285	public double eps;
286	public bool fraceps;
287	public double[] yc;
288	public double[] escale;
289	public double[] xg;
290	public int solvertype;
291	public bool needdy;
292	public double x;
293	public double[] y;
294	public double[] dy;
295	public double[,] ytbl;
296	public int repterminationtype;
297	public int repnfev;
298	public double[] yn;
299	public double[] yns;
300	public double[] rka;
301	public double[] rkc;
302	public double[] rkcs;
303	public double[,] rkb;
304	public double[,] rkk;
305	public rcommstate rstate;
306	public odesolverstate()
307	{
308	init();
309	}
310	public override void init()
311	{
312	yc = new double[0];
313	escale = new double[0];
314	xg = new double[0];
315	y = new double[0];
316	dy = new double[0];
317	ytbl = new double[0,0];
318	yn = new double[0];
319	yns = new double[0];
320	rka = new double[0];
321	rkc = new double[0];
322	rkcs = new double[0];
323	rkb = new double[0,0];
324	rkk = new double[0,0];
325	rstate = new rcommstate();
326	}
327	public override alglib.apobject make_copy()
328	{
329	odesolverstate _result = new odesolverstate();
330	_result.n = n;
331	_result.m = m;
332	_result.xscale = xscale;
333	_result.h = h;
334	_result.eps = eps;
335	_result.fraceps = fraceps;
336	_result.yc = (double[])yc.Clone();
337	_result.escale = (double[])escale.Clone();
338	_result.xg = (double[])xg.Clone();
339	_result.solvertype = solvertype;
340	_result.needdy = needdy;
341	_result.x = x;
342	_result.y = (double[])y.Clone();
343	_result.dy = (double[])dy.Clone();
344	_result.ytbl = (double[,])ytbl.Clone();
345	_result.repterminationtype = repterminationtype;
346	_result.repnfev = repnfev;
347	_result.yn = (double[])yn.Clone();
348	_result.yns = (double[])yns.Clone();
349	_result.rka = (double[])rka.Clone();
350	_result.rkc = (double[])rkc.Clone();
351	_result.rkcs = (double[])rkcs.Clone();
352	_result.rkb = (double[,])rkb.Clone();
353	_result.rkk = (double[,])rkk.Clone();
354	_result.rstate = (rcommstate)rstate.make_copy();
355	return _result;
356	}
357	};
358
359
360	public class odesolverreport : apobject
361	{
362	public int nfev;
363	public int terminationtype;
364	public odesolverreport()
365	{
366	init();
367	}
368	public override void init()
369	{
370	}
371	public override alglib.apobject make_copy()
372	{
373	odesolverreport _result = new odesolverreport();
374	_result.nfev = nfev;
375	_result.terminationtype = terminationtype;
376	return _result;
377	}
378	};
379
380
381
382
383	public const double odesolvermaxgrow = 3.0;
384	public const double odesolvermaxshrink = 10.0;
385
386
387	/*************************************************************************
388	Cash-Karp adaptive ODE solver.
389
390	This subroutine solves ODE Y'=f(Y,x) with initial conditions Y(xs)=Ys
391	(here Y may be single variable or vector of N variables).
392
393	INPUT PARAMETERS:
394	Y - initial conditions, array[0..N-1].
395	contains values of Y[] at X[0]
396	N - system size
397	X - points at which Y should be tabulated, array[0..M-1]
398	integrations starts at X[0], ends at X[M-1], intermediate
399	values at X[i] are returned too.
400	SHOULD BE ORDERED BY ASCENDING OR BY DESCENDING!
401	M - number of intermediate points + first point + last point:
402	* M>2 means that you need both Y(X[M-1]) and M-2 values at
403	intermediate points
404	* M=2 means that you want just to integrate from X[0] to
405	X[1] and don't interested in intermediate values.
406	* M=1 means that you don't want to integrate :)
407	it is degenerate case, but it will be handled correctly.
408	* M<1 means error
409	Eps - tolerance (absolute/relative error on each step will be
410	less than Eps). When passing:
411	* Eps>0, it means desired ABSOLUTE error
412	* Eps<0, it means desired RELATIVE error. Relative errors
413	are calculated with respect to maximum values of Y seen
414	so far. Be careful to use this criterion when starting
415	from Y[] that are close to zero.
416	H - initial step lenth, it will be adjusted automatically
417	after the first step. If H=0, step will be selected
418	automatically (usualy it will be equal to 0.001 of
419	min(x[i]-x[j])).
420
421	OUTPUT PARAMETERS
422	State - structure which stores algorithm state between subsequent
423	calls of OdeSolverIteration. Used for reverse communication.
424	This structure should be passed to the OdeSolverIteration
425	subroutine.
426
427	SEE ALSO
428	AutoGKSmoothW, AutoGKSingular, AutoGKIteration, AutoGKResults.
429
430
431	-- ALGLIB --
432	Copyright 01.09.2009 by Bochkanov Sergey
433	*************************************************************************/
434	public static void odesolverrkck(double[] y,
435	int n,
436	double[] x,
437	int m,
438	double eps,
439	double h,
440	odesolverstate state,
441	alglib.xparams _params)
442	{
443	alglib.ap.assert(n>=1, "ODESolverRKCK: N<1!");
444	alglib.ap.assert(m>=1, "ODESolverRKCK: M<1!");
445	alglib.ap.assert(alglib.ap.len(y)>=n, "ODESolverRKCK: Length(Y)<N!");
446	alglib.ap.assert(alglib.ap.len(x)>=m, "ODESolverRKCK: Length(X)<M!");
447	alglib.ap.assert(apserv.isfinitevector(y, n, _params), "ODESolverRKCK: Y contains infinite or NaN values!");
448	alglib.ap.assert(apserv.isfinitevector(x, m, _params), "ODESolverRKCK: Y contains infinite or NaN values!");
449	alglib.ap.assert(math.isfinite(eps), "ODESolverRKCK: Eps is not finite!");
450	alglib.ap.assert((double)(eps)!=(double)(0), "ODESolverRKCK: Eps is zero!");
451	alglib.ap.assert(math.isfinite(h), "ODESolverRKCK: H is not finite!");
452	odesolverinit(0, y, n, x, m, eps, h, state, _params);
453	}
454
455
456	/*************************************************************************
457
458	-- ALGLIB --
459	Copyright 01.09.2009 by Bochkanov Sergey
460	*************************************************************************/
461	public static bool odesolveriteration(odesolverstate state,
462	alglib.xparams _params)
463	{
464	bool result = new bool();
465	int n = 0;
466	int m = 0;
467	int i = 0;
468	int j = 0;
469	int k = 0;
470	double xc = 0;
471	double v = 0;
472	double h = 0;
473	double h2 = 0;
474	bool gridpoint = new bool();
475	double err = 0;
476	double maxgrowpow = 0;
477	int klimit = 0;
478	int i_ = 0;
479
480
481	//
482	// Reverse communication preparations
483	// I know it looks ugly, but it works the same way
484	// anywhere from C++ to Python.
485	//
486	// This code initializes locals by:
487	// * random values determined during code
488	// generation - on first subroutine call
489	// * values from previous call - on subsequent calls
490	//
491	if( state.rstate.stage>=0 )
492	{
493	n = state.rstate.ia[0];
494	m = state.rstate.ia[1];
495	i = state.rstate.ia[2];
496	j = state.rstate.ia[3];
497	k = state.rstate.ia[4];
498	klimit = state.rstate.ia[5];
499	gridpoint = state.rstate.ba[0];
500	xc = state.rstate.ra[0];
501	v = state.rstate.ra[1];
502	h = state.rstate.ra[2];
503	h2 = state.rstate.ra[3];
504	err = state.rstate.ra[4];
505	maxgrowpow = state.rstate.ra[5];
506	}
507	else
508	{
509	n = 359;
510	m = -58;
511	i = -919;
512	j = -909;
513	k = 81;
514	klimit = 255;
515	gridpoint = false;
516	xc = -788;
517	v = 809;
518	h = 205;
519	h2 = -838;
520	err = 939;
521	maxgrowpow = -526;
522	}
523	if( state.rstate.stage==0 )
524	{
525	goto lbl_0;
526	}
527
528	//
529	// Routine body
530	//
531
532	//
533	// prepare
534	//
535	if( state.repterminationtype!=0 )
536	{
537	result = false;
538	return result;
539	}
540	n = state.n;
541	m = state.m;
542	h = state.h;
543	maxgrowpow = Math.Pow(odesolvermaxgrow, 5);
544	state.repnfev = 0;
545
546	//
547	// some preliminary checks for internal errors
548	// after this we assume that H>0 and M>1
549	//
550	alglib.ap.assert((double)(state.h)>(double)(0), "ODESolver: internal error");
551	alglib.ap.assert(m>1, "ODESolverIteration: internal error");
552
553	//
554	// choose solver
555	//
556	if( state.solvertype!=0 )
557	{
558	goto lbl_1;
559	}
560
561	//
562	// Cask-Karp solver
563	// Prepare coefficients table.
564	// Check it for errors
565	//
566	state.rka = new double[6];
567	state.rka[0] = 0;
568	state.rka[1] = (double)1/(double)5;
569	state.rka[2] = (double)3/(double)10;
570	state.rka[3] = (double)3/(double)5;
571	state.rka[4] = 1;
572	state.rka[5] = (double)7/(double)8;
573	state.rkb = new double[6, 5];
574	state.rkb[1,0] = (double)1/(double)5;
575	state.rkb[2,0] = (double)3/(double)40;
576	state.rkb[2,1] = (double)9/(double)40;
577	state.rkb[3,0] = (double)3/(double)10;
578	state.rkb[3,1] = -((double)9/(double)10);
579	state.rkb[3,2] = (double)6/(double)5;
580	state.rkb[4,0] = -((double)11/(double)54);
581	state.rkb[4,1] = (double)5/(double)2;
582	state.rkb[4,2] = -((double)70/(double)27);
583	state.rkb[4,3] = (double)35/(double)27;
584	state.rkb[5,0] = (double)1631/(double)55296;
585	state.rkb[5,1] = (double)175/(double)512;
586	state.rkb[5,2] = (double)575/(double)13824;
587	state.rkb[5,3] = (double)44275/(double)110592;
588	state.rkb[5,4] = (double)253/(double)4096;
589	state.rkc = new double[6];
590	state.rkc[0] = (double)37/(double)378;
591	state.rkc[1] = 0;
592	state.rkc[2] = (double)250/(double)621;
593	state.rkc[3] = (double)125/(double)594;
594	state.rkc[4] = 0;
595	state.rkc[5] = (double)512/(double)1771;
596	state.rkcs = new double[6];
597	state.rkcs[0] = (double)2825/(double)27648;
598	state.rkcs[1] = 0;
599	state.rkcs[2] = (double)18575/(double)48384;
600	state.rkcs[3] = (double)13525/(double)55296;
601	state.rkcs[4] = (double)277/(double)14336;
602	state.rkcs[5] = (double)1/(double)4;
603	state.rkk = new double[6, n];
604
605	//
606	// Main cycle consists of two iterations:
607	// * outer where we travel from X[i-1] to X[i]
608	// * inner where we travel inside [X[i-1],X[i]]
609	//
610	state.ytbl = new double[m, n];
611	state.escale = new double[n];
612	state.yn = new double[n];
613	state.yns = new double[n];
614	xc = state.xg[0];
615	for(i_=0; i_<=n-1;i_++)
616	{
617	state.ytbl[0,i_] = state.yc[i_];
618	}
619	for(j=0; j<=n-1; j++)
620	{
621	state.escale[j] = 0;
622	}
623	i = 1;
624	lbl_3:
625	if( i>m-1 )
626	{
627	goto lbl_5;
628	}
629
630	//
631	// begin inner iteration
632	//
633	lbl_6:
634	if( false )
635	{
636	goto lbl_7;
637	}
638
639	//
640	// truncate step if needed (beyond right boundary).
641	// determine should we store X or not
642	//
643	if( (double)(xc+h)>=(double)(state.xg[i]) )
644	{
645	h = state.xg[i]-xc;
646	gridpoint = true;
647	}
648	else
649	{
650	gridpoint = false;
651	}
652
653	//
654	// Update error scale maximums
655	//
656	// These maximums are initialized by zeros,
657	// then updated every iterations.
658	//
659	for(j=0; j<=n-1; j++)
660	{
661	state.escale[j] = Math.Max(state.escale[j], Math.Abs(state.yc[j]));
662	}
663
664	//
665	// make one step:
666	// 1. calculate all info needed to do step
667	// 2. update errors scale maximums using values/derivatives
668	// obtained during (1)
669	//
670	// Take into account that we use scaling of X to reduce task
671	// to the form where x[0] < x[1] < ... < x[n-1]. So X is
672	// replaced by x=xscale*t, and dy/dx=f(y,x) is replaced
673	// by dy/dt=xscalef(y,xscalet).
674	//
675	for(i_=0; i_<=n-1;i_++)
676	{
677	state.yn[i_] = state.yc[i_];
678	}
679	for(i_=0; i_<=n-1;i_++)
680	{
681	state.yns[i_] = state.yc[i_];
682	}
683	k = 0;
684	lbl_8:
685	if( k>5 )
686	{
687	goto lbl_10;
688	}
689
690	//
691	// prepare data for the next update of YN/YNS
692	//
693	state.x = state.xscale(xc+state.rka[k]h);
694	for(i_=0; i_<=n-1;i_++)
695	{
696	state.y[i_] = state.yc[i_];
697	}
698	for(j=0; j<=k-1; j++)
699	{
700	v = state.rkb[k,j];
701	for(i_=0; i_<=n-1;i_++)
702	{
703	state.y[i_] = state.y[i_] + v*state.rkk[j,i_];
704	}
705	}
706	state.needdy = true;
707	state.rstate.stage = 0;
708	goto lbl_rcomm;
709	lbl_0:
710	state.needdy = false;
711	state.repnfev = state.repnfev+1;
712	v = h*state.xscale;
713	for(i_=0; i_<=n-1;i_++)
714	{
715	state.rkk[k,i_] = v*state.dy[i_];
716	}
717
718	//
719	// update YN/YNS
720	//
721	v = state.rkc[k];
722	for(i_=0; i_<=n-1;i_++)
723	{
724	state.yn[i_] = state.yn[i_] + v*state.rkk[k,i_];
725	}
726	v = state.rkcs[k];
727	for(i_=0; i_<=n-1;i_++)
728	{
729	state.yns[i_] = state.yns[i_] + v*state.rkk[k,i_];
730	}
731	k = k+1;
732	goto lbl_8;
733	lbl_10:
734
735	//
736	// estimate error
737	//
738	err = 0;
739	for(j=0; j<=n-1; j++)
740	{
741	if( !state.fraceps )
742	{
743
744	//
745	// absolute error is estimated
746	//
747	err = Math.Max(err, Math.Abs(state.yn[j]-state.yns[j]));
748	}
749	else
750	{
751
752	//
753	// Relative error is estimated
754	//
755	v = state.escale[j];
756	if( (double)(v)==(double)(0) )
757	{
758	v = 1;
759	}
760	err = Math.Max(err, Math.Abs(state.yn[j]-state.yns[j])/v);
761	}
762	}
763
764	//
765	// calculate new step, restart if necessary
766	//
767	if( (double)(maxgrowpow*err)<=(double)(state.eps) )
768	{
769	h2 = odesolvermaxgrow*h;
770	}
771	else
772	{
773	h2 = h*Math.Pow(state.eps/err, 0.2);
774	}
775	if( (double)(h2)<(double)(h/odesolvermaxshrink) )
776	{
777	h2 = h/odesolvermaxshrink;
778	}
779	if( (double)(err)>(double)(state.eps) )
780	{
781	h = h2;
782	goto lbl_6;
783	}
784
785	//
786	// advance position
787	//
788	xc = xc+h;
789	for(i_=0; i_<=n-1;i_++)
790	{
791	state.yc[i_] = state.yn[i_];
792	}
793
794	//
795	// update H
796	//
797	h = h2;
798
799	//
800	// break on grid point
801	//
802	if( gridpoint )
803	{
804	goto lbl_7;
805	}
806	goto lbl_6;
807	lbl_7:
808
809	//
810	// save result
811	//
812	for(i_=0; i_<=n-1;i_++)
813	{
814	state.ytbl[i,i_] = state.yc[i_];
815	}
816	i = i+1;
817	goto lbl_3;
818	lbl_5:
819	state.repterminationtype = 1;
820	result = false;
821	return result;
822	lbl_1:
823	result = false;
824	return result;
825
826	//
827	// Saving state
828	//
829	lbl_rcomm:
830	result = true;
831	state.rstate.ia[0] = n;
832	state.rstate.ia[1] = m;
833	state.rstate.ia[2] = i;
834	state.rstate.ia[3] = j;
835	state.rstate.ia[4] = k;
836	state.rstate.ia[5] = klimit;
837	state.rstate.ba[0] = gridpoint;
838	state.rstate.ra[0] = xc;
839	state.rstate.ra[1] = v;
840	state.rstate.ra[2] = h;
841	state.rstate.ra[3] = h2;
842	state.rstate.ra[4] = err;
843	state.rstate.ra[5] = maxgrowpow;
844	return result;
845	}
846
847
848	/*************************************************************************
849	ODE solver results
850
851	Called after OdeSolverIteration returned False.
852
853	INPUT PARAMETERS:
854	State - algorithm state (used by OdeSolverIteration).
855
856	OUTPUT PARAMETERS:
857	M - number of tabulated values, M>=1
858	XTbl - array[0..M-1], values of X
859	YTbl - array[0..M-1,0..N-1], values of Y in X[i]
860	Rep - solver report:
861	* Rep.TerminationType completetion code:
862	* -2 X is not ordered by ascending/descending or
863	there are non-distinct X[], i.e. X[i]=X[i+1]
864	* -1 incorrect parameters were specified
865	* 1 task has been solved
866	* Rep.NFEV contains number of function calculations
867
868	-- ALGLIB --
869	Copyright 01.09.2009 by Bochkanov Sergey
870	*************************************************************************/
871	public static void odesolverresults(odesolverstate state,
872	ref int m,
873	ref double[] xtbl,
874	ref double[,] ytbl,
875	odesolverreport rep,
876	alglib.xparams _params)
877	{
878	double v = 0;
879	int i = 0;
880	int i_ = 0;
881
882	m = 0;
883	xtbl = new double[0];
884	ytbl = new double[0,0];
885
886	rep.terminationtype = state.repterminationtype;
887	if( rep.terminationtype>0 )
888	{
889	m = state.m;
890	rep.nfev = state.repnfev;
891	xtbl = new double[state.m];
892	v = state.xscale;
893	for(i_=0; i_<=state.m-1;i_++)
894	{
895	xtbl[i_] = v*state.xg[i_];
896	}
897	ytbl = new double[state.m, state.n];
898	for(i=0; i<=state.m-1; i++)
899	{
900	for(i_=0; i_<=state.n-1;i_++)
901	{
902	ytbl[i,i_] = state.ytbl[i,i_];
903	}
904	}
905	}
906	else
907	{
908	rep.nfev = 0;
909	}
910	}
911
912
913	/*************************************************************************
914	Internal initialization subroutine
915	*************************************************************************/
916	private static void odesolverinit(int solvertype,
917	double[] y,
918	int n,
919	double[] x,
920	int m,
921	double eps,
922	double h,
923	odesolverstate state,
924	alglib.xparams _params)
925	{
926	int i = 0;
927	double v = 0;
928	int i_ = 0;
929
930
931	//
932	// Prepare RComm
933	//
934	state.rstate.ia = new int[5+1];
935	state.rstate.ba = new bool[0+1];
936	state.rstate.ra = new double[5+1];
937	state.rstate.stage = -1;
938	state.needdy = false;
939
940	//
941	// check parameters.
942	//
943	if( (n<=0 \|\| m<1) \|\| (double)(eps)==(double)(0) )
944	{
945	state.repterminationtype = -1;
946	return;
947	}
948	if( (double)(h)<(double)(0) )
949	{
950	h = -h;
951	}
952
953	//
954	// quick exit if necessary.
955	// after this block we assume that M>1
956	//
957	if( m==1 )
958	{
959	state.repnfev = 0;
960	state.repterminationtype = 1;
961	state.ytbl = new double[1, n];
962	for(i_=0; i_<=n-1;i_++)
963	{
964	state.ytbl[0,i_] = y[i_];
965	}
966	state.xg = new double[m];
967	for(i_=0; i_<=m-1;i_++)
968	{
969	state.xg[i_] = x[i_];
970	}
971	return;
972	}
973
974	//
975	// check again: correct order of X[]
976	//
977	if( (double)(x[1])==(double)(x[0]) )
978	{
979	state.repterminationtype = -2;
980	return;
981	}
982	for(i=1; i<=m-1; i++)
983	{
984	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])) )
985	{
986	state.repterminationtype = -2;
987	return;
988	}
989	}
990
991	//
992	// auto-select H if necessary
993	//
994	if( (double)(h)==(double)(0) )
995	{
996	v = Math.Abs(x[1]-x[0]);
997	for(i=2; i<=m-1; i++)
998	{
999	v = Math.Min(v, Math.Abs(x[i]-x[i-1]));
1000	}
1001	h = 0.001*v;
1002	}
1003
1004	//
1005	// store parameters
1006	//
1007	state.n = n;
1008	state.m = m;
1009	state.h = h;
1010	state.eps = Math.Abs(eps);
1011	state.fraceps = (double)(eps)<(double)(0);
1012	state.xg = new double[m];
1013	for(i_=0; i_<=m-1;i_++)
1014	{
1015	state.xg[i_] = x[i_];
1016	}
1017	if( (double)(x[1])>(double)(x[0]) )
1018	{
1019	state.xscale = 1;
1020	}
1021	else
1022	{
1023	state.xscale = -1;
1024	for(i_=0; i_<=m-1;i_++)
1025	{
1026	state.xg[i_] = -1*state.xg[i_];
1027	}
1028	}
1029	state.yc = new double[n];
1030	for(i_=0; i_<=n-1;i_++)
1031	{
1032	state.yc[i_] = y[i_];
1033	}
1034	state.solvertype = solvertype;
1035	state.repterminationtype = 0;
1036
1037	//
1038	// Allocate arrays
1039	//
1040	state.y = new double[n];
1041	state.dy = new double[n];
1042	}
1043
1044
1045	}
1046	}
1047

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