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source: trunk/sources/ALGLIB/conv.cs @ 2563

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Last change on this file since 2563 was 2563, checked in by gkronber, 15 years ago
Updated ALGLIB to latest version. #751 (Plugin for for data-modeling with ANN (integrated into CEDMA))
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1	/*************************************************************************
2	Copyright (c) 2009, 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
18	>>> END OF LICENSE >>>
19	*************************************************************************/
20
21	using System;
22
23	namespace alglib
24	{
25	public class conv
26	{
27	/*************************************************************************
28	1-dimensional complex convolution.
29
30	For given A/B returns conv(A,B) (non-circular). Subroutine can automatically
31	choose between three implementations: straightforward O(M*N) formula for
32	very small N (or M), overlap-add algorithm for cases where max(M,N) is
33	significantly larger than min(M,N), but O(M*N) algorithm is too slow, and
34	general FFT-based formula for cases where two previois algorithms are too
35	slow.
36
37	Algorithm has max(M,N)*log(max(M,N)) complexity for any M/N.
38
39	INPUT PARAMETERS
40	A - array[0..M-1] - complex function to be transformed
41	M - problem size
42	B - array[0..N-1] - complex function to be transformed
43	N - problem size
44
45	OUTPUT PARAMETERS
46	R - convolution: A*B. array[0..N+M-2].
47
48	NOTE:
49	It is assumed that A is zero at T<0, B is zero too. If one or both
50	functions have non-zero values at negative T's, you can still use this
51	subroutine - just shift its result correspondingly.
52
53	-- ALGLIB --
54	Copyright 21.07.2009 by Bochkanov Sergey
55	*************************************************************************/
56	public static void convc1d(ref AP.Complex[] a,
57	int m,
58	ref AP.Complex[] b,
59	int n,
60	ref AP.Complex[] r)
61	{
62	System.Diagnostics.Debug.Assert(n>0 & m>0, "ConvC1D: incorrect N or M!");
63
64	//
65	// normalize task: make M>=N,
66	// so A will be longer that B.
67	//
68	if( m<n )
69	{
70	convc1d(ref b, n, ref a, m, ref r);
71	return;
72	}
73	convc1dx(ref a, m, ref b, n, false, -1, 0, ref r);
74	}
75
76
77	/*************************************************************************
78	1-dimensional complex non-circular deconvolution (inverse of ConvC1D()).
79
80	Algorithm has M*log(M)) complexity for any M (composite or prime).
81
82	INPUT PARAMETERS
83	A - array[0..M-1] - convolved signal, A = conv(R, B)
84	M - convolved signal length
85	B - array[0..N-1] - response
86	N - response length, N<=M
87
88	OUTPUT PARAMETERS
89	R - deconvolved signal. array[0..M-N].
90
91	NOTE:
92	deconvolution is unstable process and may result in division by zero
93	(if your response function is degenerate, i.e. has zero Fourier coefficient).
94
95	NOTE:
96	It is assumed that A is zero at T<0, B is zero too. If one or both
97	functions have non-zero values at negative T's, you can still use this
98	subroutine - just shift its result correspondingly.
99
100	-- ALGLIB --
101	Copyright 21.07.2009 by Bochkanov Sergey
102	*************************************************************************/
103	public static void convc1dinv(ref AP.Complex[] a,
104	int m,
105	ref AP.Complex[] b,
106	int n,
107	ref AP.Complex[] r)
108	{
109	int i = 0;
110	int p = 0;
111	double[] buf = new double[0];
112	double[] buf2 = new double[0];
113	ftbase.ftplan plan = new ftbase.ftplan();
114	AP.Complex c1 = 0;
115	AP.Complex c2 = 0;
116	AP.Complex c3 = 0;
117	double t = 0;
118
119	System.Diagnostics.Debug.Assert(n>0 & m>0 & n<=m, "ConvC1DInv: incorrect N or M!");
120	p = ftbase.ftbasefindsmooth(m);
121	ftbase.ftbasegeneratecomplexfftplan(p, ref plan);
122	buf = new double[2*p];
123	for(i=0; i<=m-1; i++)
124	{
125	buf[2*i+0] = a[i].x;
126	buf[2*i+1] = a[i].y;
127	}
128	for(i=m; i<=p-1; i++)
129	{
130	buf[2*i+0] = 0;
131	buf[2*i+1] = 0;
132	}
133	buf2 = new double[2*p];
134	for(i=0; i<=n-1; i++)
135	{
136	buf2[2*i+0] = b[i].x;
137	buf2[2*i+1] = b[i].y;
138	}
139	for(i=n; i<=p-1; i++)
140	{
141	buf2[2*i+0] = 0;
142	buf2[2*i+1] = 0;
143	}
144	ftbase.ftbaseexecuteplan(ref buf, 0, p, ref plan);
145	ftbase.ftbaseexecuteplan(ref buf2, 0, p, ref plan);
146	for(i=0; i<=p-1; i++)
147	{
148	c1.x = buf[2*i+0];
149	c1.y = buf[2*i+1];
150	c2.x = buf2[2*i+0];
151	c2.y = buf2[2*i+1];
152	c3 = c1/c2;
153	buf[2*i+0] = c3.x;
154	buf[2*i+1] = -c3.y;
155	}
156	ftbase.ftbaseexecuteplan(ref buf, 0, p, ref plan);
157	t = (double)(1)/(double)(p);
158	r = new AP.Complex[m-n+1];
159	for(i=0; i<=m-n; i++)
160	{
161	r[i].x = +(tbuf[2i+0]);
162	r[i].y = -(tbuf[2i+1]);
163	}
164	}
165
166
167	/*************************************************************************
168	1-dimensional circular complex convolution.
169
170	For given S/R returns conv(S,R) (circular). Algorithm has linearithmic
171	complexity for any M/N.
172
173	IMPORTANT: normal convolution is commutative, i.e. it is symmetric -
174	conv(A,B)=conv(B,A). Cyclic convolution IS NOT. One function - S - is a
175	signal, periodic function, and another - R - is a response, non-periodic
176	function with limited length.
177
178	INPUT PARAMETERS
179	S - array[0..M-1] - complex periodic signal
180	M - problem size
181	B - array[0..N-1] - complex non-periodic response
182	N - problem size
183
184	OUTPUT PARAMETERS
185	R - convolution: A*B. array[0..M-1].
186
187	NOTE:
188	It is assumed that A is zero at T<0, B is zero too. If one or both
189	functions have non-zero values at negative T's, you can still use this
190	subroutine - just shift its result correspondingly.
191
192	-- ALGLIB --
193	Copyright 21.07.2009 by Bochkanov Sergey
194	*************************************************************************/
195	public static void convc1dcircular(ref AP.Complex[] s,
196	int m,
197	ref AP.Complex[] r,
198	int n,
199	ref AP.Complex[] c)
200	{
201	AP.Complex[] buf = new AP.Complex[0];
202	int i1 = 0;
203	int i2 = 0;
204	int j2 = 0;
205	int i_ = 0;
206	int i1_ = 0;
207
208	System.Diagnostics.Debug.Assert(n>0 & m>0, "ConvC1DCircular: incorrect N or M!");
209
210	//
211	// normalize task: make M>=N,
212	// so A will be longer (at least - not shorter) that B.
213	//
214	if( m<n )
215	{
216	buf = new AP.Complex[m];
217	for(i1=0; i1<=m-1; i1++)
218	{
219	buf[i1] = 0;
220	}
221	i1 = 0;
222	while( i1<n )
223	{
224	i2 = Math.Min(i1+m-1, n-1);
225	j2 = i2-i1;
226	i1_ = (i1) - (0);
227	for(i_=0; i_<=j2;i_++)
228	{
229	buf[i_] = buf[i_] + r[i_+i1_];
230	}
231	i1 = i1+m;
232	}
233	convc1dcircular(ref s, m, ref buf, m, ref c);
234	return;
235	}
236	convc1dx(ref s, m, ref r, n, true, -1, 0, ref c);
237	}
238
239
240	/*************************************************************************
241	1-dimensional circular complex deconvolution (inverse of ConvC1DCircular()).
242
243	Algorithm has M*log(M)) complexity for any M (composite or prime).
244
245	INPUT PARAMETERS
246	A - array[0..M-1] - convolved periodic signal, A = conv(R, B)
247	M - convolved signal length
248	B - array[0..N-1] - non-periodic response
249	N - response length
250
251	OUTPUT PARAMETERS
252	R - deconvolved signal. array[0..M-1].
253
254	NOTE:
255	deconvolution is unstable process and may result in division by zero
256	(if your response function is degenerate, i.e. has zero Fourier coefficient).
257
258	NOTE:
259	It is assumed that A is zero at T<0, B is zero too. If one or both
260	functions have non-zero values at negative T's, you can still use this
261	subroutine - just shift its result correspondingly.
262
263	-- ALGLIB --
264	Copyright 21.07.2009 by Bochkanov Sergey
265	*************************************************************************/
266	public static void convc1dcircularinv(ref AP.Complex[] a,
267	int m,
268	ref AP.Complex[] b,
269	int n,
270	ref AP.Complex[] r)
271	{
272	int i = 0;
273	int p = 0;
274	int i1 = 0;
275	int i2 = 0;
276	int j2 = 0;
277	double[] buf = new double[0];
278	double[] buf2 = new double[0];
279	AP.Complex[] cbuf = new AP.Complex[0];
280	ftbase.ftplan plan = new ftbase.ftplan();
281	AP.Complex c1 = 0;
282	AP.Complex c2 = 0;
283	AP.Complex c3 = 0;
284	double t = 0;
285	int i_ = 0;
286	int i1_ = 0;
287
288	System.Diagnostics.Debug.Assert(n>0 & m>0, "ConvC1DCircularInv: incorrect N or M!");
289
290	//
291	// normalize task: make M>=N,
292	// so A will be longer (at least - not shorter) that B.
293	//
294	if( m<n )
295	{
296	cbuf = new AP.Complex[m];
297	for(i=0; i<=m-1; i++)
298	{
299	cbuf[i] = 0;
300	}
301	i1 = 0;
302	while( i1<n )
303	{
304	i2 = Math.Min(i1+m-1, n-1);
305	j2 = i2-i1;
306	i1_ = (i1) - (0);
307	for(i_=0; i_<=j2;i_++)
308	{
309	cbuf[i_] = cbuf[i_] + b[i_+i1_];
310	}
311	i1 = i1+m;
312	}
313	convc1dcircularinv(ref a, m, ref cbuf, m, ref r);
314	return;
315	}
316
317	//
318	// Task is normalized
319	//
320	ftbase.ftbasegeneratecomplexfftplan(m, ref plan);
321	buf = new double[2*m];
322	for(i=0; i<=m-1; i++)
323	{
324	buf[2*i+0] = a[i].x;
325	buf[2*i+1] = a[i].y;
326	}
327	buf2 = new double[2*m];
328	for(i=0; i<=n-1; i++)
329	{
330	buf2[2*i+0] = b[i].x;
331	buf2[2*i+1] = b[i].y;
332	}
333	for(i=n; i<=m-1; i++)
334	{
335	buf2[2*i+0] = 0;
336	buf2[2*i+1] = 0;
337	}
338	ftbase.ftbaseexecuteplan(ref buf, 0, m, ref plan);
339	ftbase.ftbaseexecuteplan(ref buf2, 0, m, ref plan);
340	for(i=0; i<=m-1; i++)
341	{
342	c1.x = buf[2*i+0];
343	c1.y = buf[2*i+1];
344	c2.x = buf2[2*i+0];
345	c2.y = buf2[2*i+1];
346	c3 = c1/c2;
347	buf[2*i+0] = c3.x;
348	buf[2*i+1] = -c3.y;
349	}
350	ftbase.ftbaseexecuteplan(ref buf, 0, m, ref plan);
351	t = (double)(1)/(double)(m);
352	r = new AP.Complex[m];
353	for(i=0; i<=m-1; i++)
354	{
355	r[i].x = +(tbuf[2i+0]);
356	r[i].y = -(tbuf[2i+1]);
357	}
358	}
359
360
361	/*************************************************************************
362	1-dimensional real convolution.
363
364	Analogous to ConvC1D(), see ConvC1D() comments for more details.
365
366	INPUT PARAMETERS
367	A - array[0..M-1] - real function to be transformed
368	M - problem size
369	B - array[0..N-1] - real function to be transformed
370	N - problem size
371
372	OUTPUT PARAMETERS
373	R - convolution: A*B. array[0..N+M-2].
374
375	NOTE:
376	It is assumed that A is zero at T<0, B is zero too. If one or both
377	functions have non-zero values at negative T's, you can still use this
378	subroutine - just shift its result correspondingly.
379
380	-- ALGLIB --
381	Copyright 21.07.2009 by Bochkanov Sergey
382	*************************************************************************/
383	public static void convr1d(ref double[] a,
384	int m,
385	ref double[] b,
386	int n,
387	ref double[] r)
388	{
389	int i = 0;
390	int j = 0;
391	int p = 0;
392	int q = 0;
393	AP.Complex[] abuf = new AP.Complex[0];
394	AP.Complex[] bbuf = new AP.Complex[0];
395	AP.Complex v = 0;
396	double flop1 = 0;
397	double flop2 = 0;
398
399	System.Diagnostics.Debug.Assert(n>0 & m>0, "ConvR1D: incorrect N or M!");
400
401	//
402	// normalize task: make M>=N,
403	// so A will be longer that B.
404	//
405	if( m<n )
406	{
407	convr1d(ref b, n, ref a, m, ref r);
408	return;
409	}
410	convr1dx(ref a, m, ref b, n, false, -1, 0, ref r);
411	}
412
413
414	/*************************************************************************
415	1-dimensional real deconvolution (inverse of ConvC1D()).
416
417	Algorithm has M*log(M)) complexity for any M (composite or prime).
418
419	INPUT PARAMETERS
420	A - array[0..M-1] - convolved signal, A = conv(R, B)
421	M - convolved signal length
422	B - array[0..N-1] - response
423	N - response length, N<=M
424
425	OUTPUT PARAMETERS
426	R - deconvolved signal. array[0..M-N].
427
428	NOTE:
429	deconvolution is unstable process and may result in division by zero
430	(if your response function is degenerate, i.e. has zero Fourier coefficient).
431
432	NOTE:
433	It is assumed that A is zero at T<0, B is zero too. If one or both
434	functions have non-zero values at negative T's, you can still use this
435	subroutine - just shift its result correspondingly.
436
437	-- ALGLIB --
438	Copyright 21.07.2009 by Bochkanov Sergey
439	*************************************************************************/
440	public static void convr1dinv(ref double[] a,
441	int m,
442	ref double[] b,
443	int n,
444	ref double[] r)
445	{
446	int i = 0;
447	int p = 0;
448	double[] buf = new double[0];
449	double[] buf2 = new double[0];
450	double[] buf3 = new double[0];
451	ftbase.ftplan plan = new ftbase.ftplan();
452	AP.Complex c1 = 0;
453	AP.Complex c2 = 0;
454	AP.Complex c3 = 0;
455	double t = 0;
456	int i_ = 0;
457
458	System.Diagnostics.Debug.Assert(n>0 & m>0 & n<=m, "ConvR1DInv: incorrect N or M!");
459	p = ftbase.ftbasefindsmootheven(m);
460	buf = new double[p];
461	for(i_=0; i_<=m-1;i_++)
462	{
463	buf[i_] = a[i_];
464	}
465	for(i=m; i<=p-1; i++)
466	{
467	buf[i] = 0;
468	}
469	buf2 = new double[p];
470	for(i_=0; i_<=n-1;i_++)
471	{
472	buf2[i_] = b[i_];
473	}
474	for(i=n; i<=p-1; i++)
475	{
476	buf2[i] = 0;
477	}
478	buf3 = new double[p];
479	ftbase.ftbasegeneratecomplexfftplan(p/2, ref plan);
480	fft.fftr1dinternaleven(ref buf, p, ref buf3, ref plan);
481	fft.fftr1dinternaleven(ref buf2, p, ref buf3, ref plan);
482	buf[0] = buf[0]/buf2[0];
483	buf[1] = buf[1]/buf2[1];
484	for(i=1; i<=p/2-1; i++)
485	{
486	c1.x = buf[2*i+0];
487	c1.y = buf[2*i+1];
488	c2.x = buf2[2*i+0];
489	c2.y = buf2[2*i+1];
490	c3 = c1/c2;
491	buf[2*i+0] = c3.x;
492	buf[2*i+1] = c3.y;
493	}
494	fft.fftr1dinvinternaleven(ref buf, p, ref buf3, ref plan);
495	r = new double[m-n+1];
496	for(i_=0; i_<=m-n;i_++)
497	{
498	r[i_] = buf[i_];
499	}
500	}
501
502
503	/*************************************************************************
504	1-dimensional circular real convolution.
505
506	Analogous to ConvC1DCircular(), see ConvC1DCircular() comments for more details.
507
508	INPUT PARAMETERS
509	S - array[0..M-1] - real signal
510	M - problem size
511	B - array[0..N-1] - real response
512	N - problem size
513
514	OUTPUT PARAMETERS
515	R - convolution: A*B. array[0..M-1].
516
517	NOTE:
518	It is assumed that A is zero at T<0, B is zero too. If one or both
519	functions have non-zero values at negative T's, you can still use this
520	subroutine - just shift its result correspondingly.
521
522	-- ALGLIB --
523	Copyright 21.07.2009 by Bochkanov Sergey
524	*************************************************************************/
525	public static void convr1dcircular(ref double[] s,
526	int m,
527	ref double[] r,
528	int n,
529	ref double[] c)
530	{
531	double[] buf = new double[0];
532	int i1 = 0;
533	int i2 = 0;
534	int j2 = 0;
535	int i_ = 0;
536	int i1_ = 0;
537
538	System.Diagnostics.Debug.Assert(n>0 & m>0, "ConvC1DCircular: incorrect N or M!");
539
540	//
541	// normalize task: make M>=N,
542	// so A will be longer (at least - not shorter) that B.
543	//
544	if( m<n )
545	{
546	buf = new double[m];
547	for(i1=0; i1<=m-1; i1++)
548	{
549	buf[i1] = 0;
550	}
551	i1 = 0;
552	while( i1<n )
553	{
554	i2 = Math.Min(i1+m-1, n-1);
555	j2 = i2-i1;
556	i1_ = (i1) - (0);
557	for(i_=0; i_<=j2;i_++)
558	{
559	buf[i_] = buf[i_] + r[i_+i1_];
560	}
561	i1 = i1+m;
562	}
563	convr1dcircular(ref s, m, ref buf, m, ref c);
564	return;
565	}
566
567	//
568	// reduce to usual convolution
569	//
570	convr1dx(ref s, m, ref r, n, true, -1, 0, ref c);
571	}
572
573
574	/*************************************************************************
575	1-dimensional complex deconvolution (inverse of ConvC1D()).
576
577	Algorithm has M*log(M)) complexity for any M (composite or prime).
578
579	INPUT PARAMETERS
580	A - array[0..M-1] - convolved signal, A = conv(R, B)
581	M - convolved signal length
582	B - array[0..N-1] - response
583	N - response length
584
585	OUTPUT PARAMETERS
586	R - deconvolved signal. array[0..M-N].
587
588	NOTE:
589	deconvolution is unstable process and may result in division by zero
590	(if your response function is degenerate, i.e. has zero Fourier coefficient).
591
592	NOTE:
593	It is assumed that A is zero at T<0, B is zero too. If one or both
594	functions have non-zero values at negative T's, you can still use this
595	subroutine - just shift its result correspondingly.
596
597	-- ALGLIB --
598	Copyright 21.07.2009 by Bochkanov Sergey
599	*************************************************************************/
600	public static void convr1dcircularinv(ref double[] a,
601	int m,
602	ref double[] b,
603	int n,
604	ref double[] r)
605	{
606	int i = 0;
607	int i1 = 0;
608	int i2 = 0;
609	int j2 = 0;
610	double[] buf = new double[0];
611	double[] buf2 = new double[0];
612	double[] buf3 = new double[0];
613	AP.Complex[] cbuf = new AP.Complex[0];
614	AP.Complex[] cbuf2 = new AP.Complex[0];
615	ftbase.ftplan plan = new ftbase.ftplan();
616	AP.Complex c1 = 0;
617	AP.Complex c2 = 0;
618	AP.Complex c3 = 0;
619	double t = 0;
620	int i_ = 0;
621	int i1_ = 0;
622
623	System.Diagnostics.Debug.Assert(n>0 & m>0, "ConvR1DCircularInv: incorrect N or M!");
624
625	//
626	// normalize task: make M>=N,
627	// so A will be longer (at least - not shorter) that B.
628	//
629	if( m<n )
630	{
631	buf = new double[m];
632	for(i=0; i<=m-1; i++)
633	{
634	buf[i] = 0;
635	}
636	i1 = 0;
637	while( i1<n )
638	{
639	i2 = Math.Min(i1+m-1, n-1);
640	j2 = i2-i1;
641	i1_ = (i1) - (0);
642	for(i_=0; i_<=j2;i_++)
643	{
644	buf[i_] = buf[i_] + b[i_+i1_];
645	}
646	i1 = i1+m;
647	}
648	convr1dcircularinv(ref a, m, ref buf, m, ref r);
649	return;
650	}
651
652	//
653	// Task is normalized
654	//
655	if( m%2==0 )
656	{
657
658	//
659	// size is even, use fast even-size FFT
660	//
661	buf = new double[m];
662	for(i_=0; i_<=m-1;i_++)
663	{
664	buf[i_] = a[i_];
665	}
666	buf2 = new double[m];
667	for(i_=0; i_<=n-1;i_++)
668	{
669	buf2[i_] = b[i_];
670	}
671	for(i=n; i<=m-1; i++)
672	{
673	buf2[i] = 0;
674	}
675	buf3 = new double[m];
676	ftbase.ftbasegeneratecomplexfftplan(m/2, ref plan);
677	fft.fftr1dinternaleven(ref buf, m, ref buf3, ref plan);
678	fft.fftr1dinternaleven(ref buf2, m, ref buf3, ref plan);
679	buf[0] = buf[0]/buf2[0];
680	buf[1] = buf[1]/buf2[1];
681	for(i=1; i<=m/2-1; i++)
682	{
683	c1.x = buf[2*i+0];
684	c1.y = buf[2*i+1];
685	c2.x = buf2[2*i+0];
686	c2.y = buf2[2*i+1];
687	c3 = c1/c2;
688	buf[2*i+0] = c3.x;
689	buf[2*i+1] = c3.y;
690	}
691	fft.fftr1dinvinternaleven(ref buf, m, ref buf3, ref plan);
692	r = new double[m];
693	for(i_=0; i_<=m-1;i_++)
694	{
695	r[i_] = buf[i_];
696	}
697	}
698	else
699	{
700
701	//
702	// odd-size, use general real FFT
703	//
704	fft.fftr1d(ref a, m, ref cbuf);
705	buf2 = new double[m];
706	for(i_=0; i_<=n-1;i_++)
707	{
708	buf2[i_] = b[i_];
709	}
710	for(i=n; i<=m-1; i++)
711	{
712	buf2[i] = 0;
713	}
714	fft.fftr1d(ref buf2, m, ref cbuf2);
715	for(i=0; i<=(int)Math.Floor((double)(m)/(double)(2)); i++)
716	{
717	cbuf[i] = cbuf[i]/cbuf2[i];
718	}
719	fft.fftr1dinv(ref cbuf, m, ref r);
720	}
721	}
722
723
724	/*************************************************************************
725	1-dimensional complex convolution.
726
727	Extended subroutine which allows to choose convolution algorithm.
728	Intended for internal use, ALGLIB users should call ConvC1D()/ConvC1DCircular().
729
730	INPUT PARAMETERS
731	A - array[0..M-1] - complex function to be transformed
732	M - problem size
733	B - array[0..N-1] - complex function to be transformed
734	N - problem size, N<=M
735	Alg - algorithm type:
736	*-2 auto-select Q for overlap-add
737	*-1 auto-select algorithm and parameters
738	* 0 straightforward formula for small N's
739	* 1 general FFT-based code
740	* 2 overlap-add with length Q
741	Q - length for overlap-add
742
743	OUTPUT PARAMETERS
744	R - convolution: A*B. array[0..N+M-1].
745
746	-- ALGLIB --
747	Copyright 21.07.2009 by Bochkanov Sergey
748	*************************************************************************/
749	public static void convc1dx(ref AP.Complex[] a,
750	int m,
751	ref AP.Complex[] b,
752	int n,
753	bool circular,
754	int alg,
755	int q,
756	ref AP.Complex[] r)
757	{
758	int i = 0;
759	int j = 0;
760	int p = 0;
761	int ptotal = 0;
762	int i1 = 0;
763	int i2 = 0;
764	int j1 = 0;
765	int j2 = 0;
766	AP.Complex[] bbuf = new AP.Complex[0];
767	AP.Complex v = 0;
768	double ax = 0;
769	double ay = 0;
770	double bx = 0;
771	double by = 0;
772	double t = 0;
773	double tx = 0;
774	double ty = 0;
775	double flopcand = 0;
776	double flopbest = 0;
777	int algbest = 0;
778	ftbase.ftplan plan = new ftbase.ftplan();
779	double[] buf = new double[0];
780	double[] buf2 = new double[0];
781	int i_ = 0;
782	int i1_ = 0;
783
784	System.Diagnostics.Debug.Assert(n>0 & m>0, "ConvC1DX: incorrect N or M!");
785	System.Diagnostics.Debug.Assert(n<=m, "ConvC1DX: N<M assumption is false!");
786
787	//
788	// Auto-select
789	//
790	if( alg==-1 \| alg==-2 )
791	{
792
793	//
794	// Initial candidate: straightforward implementation.
795	//
796	// If we want to use auto-fitted overlap-add,
797	// flop count is initialized by large real number - to force
798	// another algorithm selection
799	//
800	algbest = 0;
801	if( alg==-1 )
802	{
803	flopbest = 2mn;
804	}
805	else
806	{
807	flopbest = AP.Math.MaxRealNumber;
808	}
809
810	//
811	// Another candidate - generic FFT code
812	//
813	if( alg==-1 )
814	{
815	if( circular & ftbase.ftbaseissmooth(m) )
816	{
817
818	//
819	// special code for circular convolution of a sequence with a smooth length
820	//
821	flopcand = 3ftbase.ftbasegetflopestimate(m)+6m;
822	if( (double)(flopcand)<(double)(flopbest) )
823	{
824	algbest = 1;
825	flopbest = flopcand;
826	}
827	}
828	else
829	{
830
831	//
832	// general cyclic/non-cyclic convolution
833	//
834	p = ftbase.ftbasefindsmooth(m+n-1);
835	flopcand = 3ftbase.ftbasegetflopestimate(p)+6p;
836	if( (double)(flopcand)<(double)(flopbest) )
837	{
838	algbest = 1;
839	flopbest = flopcand;
840	}
841	}
842	}
843
844	//
845	// Another candidate - overlap-add
846	//
847	q = 1;
848	ptotal = 1;
849	while( ptotal<n )
850	{
851	ptotal = ptotal*2;
852	}
853	while( ptotal<=m+n-1 )
854	{
855	p = ptotal-n+1;
856	flopcand = (int)Math.Ceiling((double)(m)/(double)(p))(2ftbase.ftbasegetflopestimate(ptotal)+8*ptotal);
857	if( (double)(flopcand)<(double)(flopbest) )
858	{
859	flopbest = flopcand;
860	algbest = 2;
861	q = p;
862	}
863	ptotal = ptotal*2;
864	}
865	alg = algbest;
866	convc1dx(ref a, m, ref b, n, circular, alg, q, ref r);
867	return;
868	}
869
870	//
871	// straightforward formula for
872	// circular and non-circular convolutions.
873	//
874	// Very simple code, no further comments needed.
875	//
876	if( alg==0 )
877	{
878
879	//
880	// Special case: N=1
881	//
882	if( n==1 )
883	{
884	r = new AP.Complex[m];
885	v = b[0];
886	for(i_=0; i_<=m-1;i_++)
887	{
888	r[i_] = v*a[i_];
889	}
890	return;
891	}
892
893	//
894	// use straightforward formula
895	//
896	if( circular )
897	{
898
899	//
900	// circular convolution
901	//
902	r = new AP.Complex[m];
903	v = b[0];
904	for(i_=0; i_<=m-1;i_++)
905	{
906	r[i_] = v*a[i_];
907	}
908	for(i=1; i<=n-1; i++)
909	{
910	v = b[i];
911	i1 = 0;
912	i2 = i-1;
913	j1 = m-i;
914	j2 = m-1;
915	i1_ = (j1) - (i1);
916	for(i_=i1; i_<=i2;i_++)
917	{
918	r[i_] = r[i_] + v*a[i_+i1_];
919	}
920	i1 = i;
921	i2 = m-1;
922	j1 = 0;
923	j2 = m-i-1;
924	i1_ = (j1) - (i1);
925	for(i_=i1; i_<=i2;i_++)
926	{
927	r[i_] = r[i_] + v*a[i_+i1_];
928	}
929	}
930	}
931	else
932	{
933
934	//
935	// non-circular convolution
936	//
937	r = new AP.Complex[m+n-1];
938	for(i=0; i<=m+n-2; i++)
939	{
940	r[i] = 0;
941	}
942	for(i=0; i<=n-1; i++)
943	{
944	v = b[i];
945	i1_ = (0) - (i);
946	for(i_=i; i_<=i+m-1;i_++)
947	{
948	r[i_] = r[i_] + v*a[i_+i1_];
949	}
950	}
951	}
952	return;
953	}
954
955	//
956	// general FFT-based code for
957	// circular and non-circular convolutions.
958	//
959	// First, if convolution is circular, we test whether M is smooth or not.
960	// If it is smooth, we just use M-length FFT to calculate convolution.
961	// If it is not, we calculate non-circular convolution and wrap it arount.
962	//
963	// IF convolution is non-circular, we use zero-padding + FFT.
964	//
965	if( alg==1 )
966	{
967	if( circular & ftbase.ftbaseissmooth(m) )
968	{
969
970	//
971	// special code for circular convolution with smooth M
972	//
973	ftbase.ftbasegeneratecomplexfftplan(m, ref plan);
974	buf = new double[2*m];
975	for(i=0; i<=m-1; i++)
976	{
977	buf[2*i+0] = a[i].x;
978	buf[2*i+1] = a[i].y;
979	}
980	buf2 = new double[2*m];
981	for(i=0; i<=n-1; i++)
982	{
983	buf2[2*i+0] = b[i].x;
984	buf2[2*i+1] = b[i].y;
985	}
986	for(i=n; i<=m-1; i++)
987	{
988	buf2[2*i+0] = 0;
989	buf2[2*i+1] = 0;
990	}
991	ftbase.ftbaseexecuteplan(ref buf, 0, m, ref plan);
992	ftbase.ftbaseexecuteplan(ref buf2, 0, m, ref plan);
993	for(i=0; i<=m-1; i++)
994	{
995	ax = buf[2*i+0];
996	ay = buf[2*i+1];
997	bx = buf2[2*i+0];
998	by = buf2[2*i+1];
999	tx = axbx-ayby;
1000	ty = axby+aybx;
1001	buf[2*i+0] = tx;
1002	buf[2*i+1] = -ty;
1003	}
1004	ftbase.ftbaseexecuteplan(ref buf, 0, m, ref plan);
1005	t = (double)(1)/(double)(m);
1006	r = new AP.Complex[m];
1007	for(i=0; i<=m-1; i++)
1008	{
1009	r[i].x = +(tbuf[2i+0]);
1010	r[i].y = -(tbuf[2i+1]);
1011	}
1012	}
1013	else
1014	{
1015
1016	//
1017	// M is non-smooth, general code (circular/non-circular):
1018	// * first part is the same for circular and non-circular
1019	// convolutions. zero padding, FFTs, inverse FFTs
1020	// * second part differs:
1021	// * for non-circular convolution we just copy array
1022	// * for circular convolution we add array tail to its head
1023	//
1024	p = ftbase.ftbasefindsmooth(m+n-1);
1025	ftbase.ftbasegeneratecomplexfftplan(p, ref plan);
1026	buf = new double[2*p];
1027	for(i=0; i<=m-1; i++)
1028	{
1029	buf[2*i+0] = a[i].x;
1030	buf[2*i+1] = a[i].y;
1031	}
1032	for(i=m; i<=p-1; i++)
1033	{
1034	buf[2*i+0] = 0;
1035	buf[2*i+1] = 0;
1036	}
1037	buf2 = new double[2*p];
1038	for(i=0; i<=n-1; i++)
1039	{
1040	buf2[2*i+0] = b[i].x;
1041	buf2[2*i+1] = b[i].y;
1042	}
1043	for(i=n; i<=p-1; i++)
1044	{
1045	buf2[2*i+0] = 0;
1046	buf2[2*i+1] = 0;
1047	}
1048	ftbase.ftbaseexecuteplan(ref buf, 0, p, ref plan);
1049	ftbase.ftbaseexecuteplan(ref buf2, 0, p, ref plan);
1050	for(i=0; i<=p-1; i++)
1051	{
1052	ax = buf[2*i+0];
1053	ay = buf[2*i+1];
1054	bx = buf2[2*i+0];
1055	by = buf2[2*i+1];
1056	tx = axbx-ayby;
1057	ty = axby+aybx;
1058	buf[2*i+0] = tx;
1059	buf[2*i+1] = -ty;
1060	}
1061	ftbase.ftbaseexecuteplan(ref buf, 0, p, ref plan);
1062	t = (double)(1)/(double)(p);
1063	if( circular )
1064	{
1065
1066	//
1067	// circular, add tail to head
1068	//
1069	r = new AP.Complex[m];
1070	for(i=0; i<=m-1; i++)
1071	{
1072	r[i].x = +(tbuf[2i+0]);
1073	r[i].y = -(tbuf[2i+1]);
1074	}
1075	for(i=m; i<=m+n-2; i++)
1076	{
1077	r[i-m].x = r[i-m].x+tbuf[2i+0];
1078	r[i-m].y = r[i-m].y-tbuf[2i+1];
1079	}
1080	}
1081	else
1082	{
1083
1084	//
1085	// non-circular, just copy
1086	//
1087	r = new AP.Complex[m+n-1];
1088	for(i=0; i<=m+n-2; i++)
1089	{
1090	r[i].x = +(tbuf[2i+0]);
1091	r[i].y = -(tbuf[2i+1]);
1092	}
1093	}
1094	}
1095	return;
1096	}
1097
1098	//
1099	// overlap-add method for
1100	// circular and non-circular convolutions.
1101	//
1102	// First part of code (separate FFTs of input blocks) is the same
1103	// for all types of convolution. Second part (overlapping outputs)
1104	// differs for different types of convolution. We just copy output
1105	// when convolution is non-circular. We wrap it around, if it is
1106	// circular.
1107	//
1108	if( alg==2 )
1109	{
1110	buf = new double[2*(q+n-1)];
1111
1112	//
1113	// prepare R
1114	//
1115	if( circular )
1116	{
1117	r = new AP.Complex[m];
1118	for(i=0; i<=m-1; i++)
1119	{
1120	r[i] = 0;
1121	}
1122	}
1123	else
1124	{
1125	r = new AP.Complex[m+n-1];
1126	for(i=0; i<=m+n-2; i++)
1127	{
1128	r[i] = 0;
1129	}
1130	}
1131
1132	//
1133	// pre-calculated FFT(B)
1134	//
1135	bbuf = new AP.Complex[q+n-1];
1136	for(i_=0; i_<=n-1;i_++)
1137	{
1138	bbuf[i_] = b[i_];
1139	}
1140	for(j=n; j<=q+n-2; j++)
1141	{
1142	bbuf[j] = 0;
1143	}
1144	fft.fftc1d(ref bbuf, q+n-1);
1145
1146	//
1147	// prepare FFT plan for chunks of A
1148	//
1149	ftbase.ftbasegeneratecomplexfftplan(q+n-1, ref plan);
1150
1151	//
1152	// main overlap-add cycle
1153	//
1154	i = 0;
1155	while( i<=m-1 )
1156	{
1157	p = Math.Min(q, m-i);
1158	for(j=0; j<=p-1; j++)
1159	{
1160	buf[2*j+0] = a[i+j].x;
1161	buf[2*j+1] = a[i+j].y;
1162	}
1163	for(j=p; j<=q+n-2; j++)
1164	{
1165	buf[2*j+0] = 0;
1166	buf[2*j+1] = 0;
1167	}
1168	ftbase.ftbaseexecuteplan(ref buf, 0, q+n-1, ref plan);
1169	for(j=0; j<=q+n-2; j++)
1170	{
1171	ax = buf[2*j+0];
1172	ay = buf[2*j+1];
1173	bx = bbuf[j].x;
1174	by = bbuf[j].y;
1175	tx = axbx-ayby;
1176	ty = axby+aybx;
1177	buf[2*j+0] = tx;
1178	buf[2*j+1] = -ty;
1179	}
1180	ftbase.ftbaseexecuteplan(ref buf, 0, q+n-1, ref plan);
1181	t = (double)(1)/((double)(q+n-1));
1182	if( circular )
1183	{
1184	j1 = Math.Min(i+p+n-2, m-1)-i;
1185	j2 = j1+1;
1186	}
1187	else
1188	{
1189	j1 = p+n-2;
1190	j2 = j1+1;
1191	}
1192	for(j=0; j<=j1; j++)
1193	{
1194	r[i+j].x = r[i+j].x+buf[2j+0]t;
1195	r[i+j].y = r[i+j].y-buf[2j+1]t;
1196	}
1197	for(j=j2; j<=p+n-2; j++)
1198	{
1199	r[j-j2].x = r[j-j2].x+buf[2j+0]t;
1200	r[j-j2].y = r[j-j2].y-buf[2j+1]t;
1201	}
1202	i = i+p;
1203	}
1204	return;
1205	}
1206	}
1207
1208
1209	/*************************************************************************
1210	1-dimensional real convolution.
1211
1212	Extended subroutine which allows to choose convolution algorithm.
1213	Intended for internal use, ALGLIB users should call ConvR1D().
1214
1215	INPUT PARAMETERS
1216	A - array[0..M-1] - complex function to be transformed
1217	M - problem size
1218	B - array[0..N-1] - complex function to be transformed
1219	N - problem size, N<=M
1220	Alg - algorithm type:
1221	*-2 auto-select Q for overlap-add
1222	*-1 auto-select algorithm and parameters
1223	* 0 straightforward formula for small N's
1224	* 1 general FFT-based code
1225	* 2 overlap-add with length Q
1226	Q - length for overlap-add
1227
1228	OUTPUT PARAMETERS
1229	R - convolution: A*B. array[0..N+M-1].
1230
1231	-- ALGLIB --
1232	Copyright 21.07.2009 by Bochkanov Sergey
1233	*************************************************************************/
1234	public static void convr1dx(ref double[] a,
1235	int m,
1236	ref double[] b,
1237	int n,
1238	bool circular,
1239	int alg,
1240	int q,
1241	ref double[] r)
1242	{
1243	double v = 0;
1244	int i = 0;
1245	int j = 0;
1246	int p = 0;
1247	int ptotal = 0;
1248	int i1 = 0;
1249	int i2 = 0;
1250	int j1 = 0;
1251	int j2 = 0;
1252	double ax = 0;
1253	double ay = 0;
1254	double bx = 0;
1255	double by = 0;
1256	double t = 0;
1257	double tx = 0;
1258	double ty = 0;
1259	double flopcand = 0;
1260	double flopbest = 0;
1261	int algbest = 0;
1262	ftbase.ftplan plan = new ftbase.ftplan();
1263	double[] buf = new double[0];
1264	double[] buf2 = new double[0];
1265	double[] buf3 = new double[0];
1266	int i_ = 0;
1267	int i1_ = 0;
1268
1269	System.Diagnostics.Debug.Assert(n>0 & m>0, "ConvC1DX: incorrect N or M!");
1270	System.Diagnostics.Debug.Assert(n<=m, "ConvC1DX: N<M assumption is false!");
1271
1272	//
1273	// handle special cases
1274	//
1275	if( Math.Min(m, n)<=2 )
1276	{
1277	alg = 0;
1278	}
1279
1280	//
1281	// Auto-select
1282	//
1283	if( alg<0 )
1284	{
1285
1286	//
1287	// Initial candidate: straightforward implementation.
1288	//
1289	// If we want to use auto-fitted overlap-add,
1290	// flop count is initialized by large real number - to force
1291	// another algorithm selection
1292	//
1293	algbest = 0;
1294	if( alg==-1 )
1295	{
1296	flopbest = 0.15mn;
1297	}
1298	else
1299	{
1300	flopbest = AP.Math.MaxRealNumber;
1301	}
1302
1303	//
1304	// Another candidate - generic FFT code
1305	//
1306	if( alg==-1 )
1307	{
1308	if( circular & ftbase.ftbaseissmooth(m) & m%2==0 )
1309	{
1310
1311	//
1312	// special code for circular convolution of a sequence with a smooth length
1313	//
1314	flopcand = 3ftbase.ftbasegetflopestimate(m/2)+(double)(6m)/(double)(2);
1315	if( (double)(flopcand)<(double)(flopbest) )
1316	{
1317	algbest = 1;
1318	flopbest = flopcand;
1319	}
1320	}
1321	else
1322	{
1323
1324	//
1325	// general cyclic/non-cyclic convolution
1326	//
1327	p = ftbase.ftbasefindsmootheven(m+n-1);
1328	flopcand = 3ftbase.ftbasegetflopestimate(p/2)+(double)(6p)/(double)(2);
1329	if( (double)(flopcand)<(double)(flopbest) )
1330	{
1331	algbest = 1;
1332	flopbest = flopcand;
1333	}
1334	}
1335	}
1336
1337	//
1338	// Another candidate - overlap-add
1339	//
1340	q = 1;
1341	ptotal = 1;
1342	while( ptotal<n )
1343	{
1344	ptotal = ptotal*2;
1345	}
1346	while( ptotal<=m+n-1 )
1347	{
1348	p = ptotal-n+1;
1349	flopcand = (int)Math.Ceiling((double)(m)/(double)(p))(2ftbase.ftbasegetflopestimate(ptotal/2)+1*(ptotal/2));
1350	if( (double)(flopcand)<(double)(flopbest) )
1351	{
1352	flopbest = flopcand;
1353	algbest = 2;
1354	q = p;
1355	}
1356	ptotal = ptotal*2;
1357	}
1358	alg = algbest;
1359	convr1dx(ref a, m, ref b, n, circular, alg, q, ref r);
1360	return;
1361	}
1362
1363	//
1364	// straightforward formula for
1365	// circular and non-circular convolutions.
1366	//
1367	// Very simple code, no further comments needed.
1368	//
1369	if( alg==0 )
1370	{
1371
1372	//
1373	// Special case: N=1
1374	//
1375	if( n==1 )
1376	{
1377	r = new double[m];
1378	v = b[0];
1379	for(i_=0; i_<=m-1;i_++)
1380	{
1381	r[i_] = v*a[i_];
1382	}
1383	return;
1384	}
1385
1386	//
1387	// use straightforward formula
1388	//
1389	if( circular )
1390	{
1391
1392	//
1393	// circular convolution
1394	//
1395	r = new double[m];
1396	v = b[0];
1397	for(i_=0; i_<=m-1;i_++)
1398	{
1399	r[i_] = v*a[i_];
1400	}
1401	for(i=1; i<=n-1; i++)
1402	{
1403	v = b[i];
1404	i1 = 0;
1405	i2 = i-1;
1406	j1 = m-i;
1407	j2 = m-1;
1408	i1_ = (j1) - (i1);
1409	for(i_=i1; i_<=i2;i_++)
1410	{
1411	r[i_] = r[i_] + v*a[i_+i1_];
1412	}
1413	i1 = i;
1414	i2 = m-1;
1415	j1 = 0;
1416	j2 = m-i-1;
1417	i1_ = (j1) - (i1);
1418	for(i_=i1; i_<=i2;i_++)
1419	{
1420	r[i_] = r[i_] + v*a[i_+i1_];
1421	}
1422	}
1423	}
1424	else
1425	{
1426
1427	//
1428	// non-circular convolution
1429	//
1430	r = new double[m+n-1];
1431	for(i=0; i<=m+n-2; i++)
1432	{
1433	r[i] = 0;
1434	}
1435	for(i=0; i<=n-1; i++)
1436	{
1437	v = b[i];
1438	i1_ = (0) - (i);
1439	for(i_=i; i_<=i+m-1;i_++)
1440	{
1441	r[i_] = r[i_] + v*a[i_+i1_];
1442	}
1443	}
1444	}
1445	return;
1446	}
1447
1448	//
1449	// general FFT-based code for
1450	// circular and non-circular convolutions.
1451	//
1452	// First, if convolution is circular, we test whether M is smooth or not.
1453	// If it is smooth, we just use M-length FFT to calculate convolution.
1454	// If it is not, we calculate non-circular convolution and wrap it arount.
1455	//
1456	// If convolution is non-circular, we use zero-padding + FFT.
1457	//
1458	// We assume that M+N-1>2 - we should call small case code otherwise
1459	//
1460	if( alg==1 )
1461	{
1462	System.Diagnostics.Debug.Assert(m+n-1>2, "ConvR1DX: internal error!");
1463	if( circular & ftbase.ftbaseissmooth(m) & m%2==0 )
1464	{
1465
1466	//
1467	// special code for circular convolution with smooth even M
1468	//
1469	buf = new double[m];
1470	for(i_=0; i_<=m-1;i_++)
1471	{
1472	buf[i_] = a[i_];
1473	}
1474	buf2 = new double[m];
1475	for(i_=0; i_<=n-1;i_++)
1476	{
1477	buf2[i_] = b[i_];
1478	}
1479	for(i=n; i<=m-1; i++)
1480	{
1481	buf2[i] = 0;
1482	}
1483	buf3 = new double[m];
1484	ftbase.ftbasegeneratecomplexfftplan(m/2, ref plan);
1485	fft.fftr1dinternaleven(ref buf, m, ref buf3, ref plan);
1486	fft.fftr1dinternaleven(ref buf2, m, ref buf3, ref plan);
1487	buf[0] = buf[0]*buf2[0];
1488	buf[1] = buf[1]*buf2[1];
1489	for(i=1; i<=m/2-1; i++)
1490	{
1491	ax = buf[2*i+0];
1492	ay = buf[2*i+1];
1493	bx = buf2[2*i+0];
1494	by = buf2[2*i+1];
1495	tx = axbx-ayby;
1496	ty = axby+aybx;
1497	buf[2*i+0] = tx;
1498	buf[2*i+1] = ty;
1499	}
1500	fft.fftr1dinvinternaleven(ref buf, m, ref buf3, ref plan);
1501	r = new double[m];
1502	for(i_=0; i_<=m-1;i_++)
1503	{
1504	r[i_] = buf[i_];
1505	}
1506	}
1507	else
1508	{
1509
1510	//
1511	// M is non-smooth or non-even, general code (circular/non-circular):
1512	// * first part is the same for circular and non-circular
1513	// convolutions. zero padding, FFTs, inverse FFTs
1514	// * second part differs:
1515	// * for non-circular convolution we just copy array
1516	// * for circular convolution we add array tail to its head
1517	//
1518	p = ftbase.ftbasefindsmootheven(m+n-1);
1519	buf = new double[p];
1520	for(i_=0; i_<=m-1;i_++)
1521	{
1522	buf[i_] = a[i_];
1523	}
1524	for(i=m; i<=p-1; i++)
1525	{
1526	buf[i] = 0;
1527	}
1528	buf2 = new double[p];
1529	for(i_=0; i_<=n-1;i_++)
1530	{
1531	buf2[i_] = b[i_];
1532	}
1533	for(i=n; i<=p-1; i++)
1534	{
1535	buf2[i] = 0;
1536	}
1537	buf3 = new double[p];
1538	ftbase.ftbasegeneratecomplexfftplan(p/2, ref plan);
1539	fft.fftr1dinternaleven(ref buf, p, ref buf3, ref plan);
1540	fft.fftr1dinternaleven(ref buf2, p, ref buf3, ref plan);
1541	buf[0] = buf[0]*buf2[0];
1542	buf[1] = buf[1]*buf2[1];
1543	for(i=1; i<=p/2-1; i++)
1544	{
1545	ax = buf[2*i+0];
1546	ay = buf[2*i+1];
1547	bx = buf2[2*i+0];
1548	by = buf2[2*i+1];
1549	tx = axbx-ayby;
1550	ty = axby+aybx;
1551	buf[2*i+0] = tx;
1552	buf[2*i+1] = ty;
1553	}
1554	fft.fftr1dinvinternaleven(ref buf, p, ref buf3, ref plan);
1555	if( circular )
1556	{
1557
1558	//
1559	// circular, add tail to head
1560	//
1561	r = new double[m];
1562	for(i_=0; i_<=m-1;i_++)
1563	{
1564	r[i_] = buf[i_];
1565	}
1566	if( n>=2 )
1567	{
1568	i1_ = (m) - (0);
1569	for(i_=0; i_<=n-2;i_++)
1570	{
1571	r[i_] = r[i_] + buf[i_+i1_];
1572	}
1573	}
1574	}
1575	else
1576	{
1577
1578	//
1579	// non-circular, just copy
1580	//
1581	r = new double[m+n-1];
1582	for(i_=0; i_<=m+n-2;i_++)
1583	{
1584	r[i_] = buf[i_];
1585	}
1586	}
1587	}
1588	return;
1589	}
1590
1591	//
1592	// overlap-add method
1593	//
1594	if( alg==2 )
1595	{
1596	System.Diagnostics.Debug.Assert((q+n-1)%2==0, "ConvR1DX: internal error!");
1597	buf = new double[q+n-1];
1598	buf2 = new double[q+n-1];
1599	buf3 = new double[q+n-1];
1600	ftbase.ftbasegeneratecomplexfftplan((q+n-1)/2, ref plan);
1601
1602	//
1603	// prepare R
1604	//
1605	if( circular )
1606	{
1607	r = new double[m];
1608	for(i=0; i<=m-1; i++)
1609	{
1610	r[i] = 0;
1611	}
1612	}
1613	else
1614	{
1615	r = new double[m+n-1];
1616	for(i=0; i<=m+n-2; i++)
1617	{
1618	r[i] = 0;
1619	}
1620	}
1621
1622	//
1623	// pre-calculated FFT(B)
1624	//
1625	for(i_=0; i_<=n-1;i_++)
1626	{
1627	buf2[i_] = b[i_];
1628	}
1629	for(j=n; j<=q+n-2; j++)
1630	{
1631	buf2[j] = 0;
1632	}
1633	fft.fftr1dinternaleven(ref buf2, q+n-1, ref buf3, ref plan);
1634
1635	//
1636	// main overlap-add cycle
1637	//
1638	i = 0;
1639	while( i<=m-1 )
1640	{
1641	p = Math.Min(q, m-i);
1642	i1_ = (i) - (0);
1643	for(i_=0; i_<=p-1;i_++)
1644	{
1645	buf[i_] = a[i_+i1_];
1646	}
1647	for(j=p; j<=q+n-2; j++)
1648	{
1649	buf[j] = 0;
1650	}
1651	fft.fftr1dinternaleven(ref buf, q+n-1, ref buf3, ref plan);
1652	buf[0] = buf[0]*buf2[0];
1653	buf[1] = buf[1]*buf2[1];
1654	for(j=1; j<=(q+n-1)/2-1; j++)
1655	{
1656	ax = buf[2*j+0];
1657	ay = buf[2*j+1];
1658	bx = buf2[2*j+0];
1659	by = buf2[2*j+1];
1660	tx = axbx-ayby;
1661	ty = axby+aybx;
1662	buf[2*j+0] = tx;
1663	buf[2*j+1] = ty;
1664	}
1665	fft.fftr1dinvinternaleven(ref buf, q+n-1, ref buf3, ref plan);
1666	if( circular )
1667	{
1668	j1 = Math.Min(i+p+n-2, m-1)-i;
1669	j2 = j1+1;
1670	}
1671	else
1672	{
1673	j1 = p+n-2;
1674	j2 = j1+1;
1675	}
1676	i1_ = (0) - (i);
1677	for(i_=i; i_<=i+j1;i_++)
1678	{
1679	r[i_] = r[i_] + buf[i_+i1_];
1680	}
1681	if( p+n-2>=j2 )
1682	{
1683	i1_ = (j2) - (0);
1684	for(i_=0; i_<=p+n-2-j2;i_++)
1685	{
1686	r[i_] = r[i_] + buf[i_+i1_];
1687	}
1688	}
1689	i = i+p;
1690	}
1691	return;
1692	}
1693	}
1694	}
1695	}

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