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source: branches/HeuristicLab.Problems.GaussianProcessTuning/ILNumerics.2.14.4735.573/Functions/builtin/isfinite.cs @ 9407

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Last change on this file since 9407 was 9102, checked in by gkronber, 12 years ago
#1967: ILNumerics source for experimentation
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1	///
2	/// This file is part of ILNumerics Community Edition.
3	///
4	/// ILNumerics Community Edition - high performance computing for applications.
5	/// Copyright (C) 2006 - 2012 Haymo Kutschbach, http://ilnumerics.net
6	///
7	/// ILNumerics Community Edition is free software: you can redistribute it and/or modify
8	/// it under the terms of the GNU General Public License version 3 as published by
9	/// the Free Software Foundation.
10	///
11	/// ILNumerics Community Edition 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	/// You should have received a copy of the GNU General Public License
17	/// along with ILNumerics Community Edition. See the file License.txt in the root
18	/// of your distribution package. If not, see <http://www.gnu.org/licenses/>.
19	///
20	/// In addition this software uses the following components and/or licenses:
21	///
22	/// =================================================================================
23	/// The Open Toolkit Library License
24	///
25	/// Copyright (c) 2006 - 2009 the Open Toolkit library.
26	///
27	/// Permission is hereby granted, free of charge, to any person obtaining a copy
28	/// of this software and associated documentation files (the "Software"), to deal
29	/// in the Software without restriction, including without limitation the rights to
30	/// use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of
31	/// the Software, and to permit persons to whom the Software is furnished to do
32	/// so, subject to the following conditions:
33	///
34	/// The above copyright notice and this permission notice shall be included in all
35	/// copies or substantial portions of the Software.
36	///
37	/// =================================================================================
38	///
39
40	using System;
41	using System.Collections.Generic;
42	using System.Text;
43	using ILNumerics;
44	using ILNumerics.Exceptions;
45	using ILNumerics.Storage;
46	using ILNumerics.Misc;
47
48
49
50	namespace ILNumerics {
51
52	public partial class ILMath {
53	/// <summary>
54	/// Find out, if value is finite
55	/// </summary>
56	/// <param name="input">Input value</param>
57	/// <returns>True for finite values</returns>
58	internal static bool isfinite(double input) {
59	if (!double.IsInfinity(input) && !double.IsNaN(input))
60	return true;
61	else
62	return false;
63	}
64	/// <summary>
65	/// Find out, if value is finite
66	/// </summary>
67	/// <param name="input">Input value</param>
68	/// <returns>True for finite values</returns>
69	internal static bool isfinite(complex input) {
70	if (!complex.IsInfinity(input) && !complex.IsNaN(input))
71	return true;
72	else
73	return false;
74	}
75	/// <summary>
76	/// Find out, if value is finite
77	/// </summary>
78	/// <param name="input">Input value</param>
79	/// <returns>True for finite values</returns>
80	internal static bool isfinite(float input) {
81	if (!float.IsInfinity(input) && !float.IsNaN(input))
82	return true;
83	else
84	return false;
85	}
86	/// <summary>
87	/// Find out, if value is finite
88	/// </summary>
89	/// <param name="input">Input value</param>
90	/// <returns>True for finite values</returns>
91	internal static bool isfinite(fcomplex input) {
92	if (!fcomplex.IsInfinity(input) && !fcomplex.IsNaN(input))
93	return true;
94	else
95	return false;
96	}
97
98
99
100
101	#region HYCALPER AUTO GENERATED CODE
102
103	/// <summary>Finds finite value elements</summary>
104	/// <param name="A">Input array</param>
105	/// <returns>Logical array with 1 if the corresponding elements of input array is finite, 0 else.</returns>
106	/// <remarks><para>If the input array is empty, an empty array will be returned.</para>
107	/// <para>The array returned will be a dense array.</para></remarks>
108	public unsafe static ILRetLogical isfinite (ILInArray< double > A) {
109	using (ILScope.Enter(A)) {
110	if (A.IsEmpty)
111	return new ILRetLogical(A.Size);
112	ILSize inDim = A.Size;
113	double[] arrA = A.GetArrayForRead();
114	byte [] retArr;
115	int outLen = inDim.NumberOfElements;
116	bool inplace = true;
117
118	if (true){
119	retArr = ILMemoryPool.Pool.New<byte>(outLen);
120	inplace = false;
121	}
122	int i = 0, workItemCount = Settings.s_maxNumberThreads, workItemLength, workerCount = 1;
123	if (Settings.s_maxNumberThreads > 1 && outLen / 2 > Settings.s_minParallelElement1Count) {
124	if (outLen / workItemCount > Settings.s_minParallelElement1Count) {
125	workItemLength = outLen / workItemCount;
126	//workItemLength = (int)((double)outLen / workItemCount * 1.05);
127	} else {
128	workItemLength = outLen / 2;
129	workItemCount = 2;
130	}
131	} else {
132	workItemLength = outLen;
133	workItemCount = 1;
134	}
135	ILDenseStorage<byte> retStorage = new ILDenseStorage<byte>(retArr, inDim);
136
137	Action<object> worker = data => {
138	Tuple<int, int, IntPtr, IntPtr, bool> range = (Tuple<int, int, IntPtr, IntPtr, bool>)data;
139
140	byte* cp = ((byte*)range.Item4 + range.Item1);
141	int len = range.Item2;
142	if (range.Item5) {
143	// inplace
144	while (len > 20) {
145	cp[0] = isfinite(cp[0] ) ?(byte)1:(byte)0;;
146	cp[1] = isfinite(cp[1] ) ?(byte)1:(byte)0;;
147	cp[2] = isfinite(cp[2] ) ?(byte)1:(byte)0;;
148	cp[3] = isfinite(cp[3] ) ?(byte)1:(byte)0;;
149	cp[4] = isfinite(cp[4] ) ?(byte)1:(byte)0;;
150	cp[5] = isfinite(cp[5] ) ?(byte)1:(byte)0;;
151	cp[6] = isfinite(cp[6] ) ?(byte)1:(byte)0;;
152	cp[7] = isfinite(cp[7] ) ?(byte)1:(byte)0;;
153	cp[8] = isfinite(cp[8] ) ?(byte)1:(byte)0;;
154	cp[9] = isfinite(cp[9] ) ?(byte)1:(byte)0;;
155	cp[10] = isfinite(cp[10] ) ?(byte)1:(byte)0;;
156	cp[11] = isfinite(cp[11] ) ?(byte)1:(byte)0;;
157	cp[12] = isfinite(cp[12] ) ?(byte)1:(byte)0;;
158	cp[13] = isfinite(cp[13] ) ?(byte)1:(byte)0;;
159	cp[14] = isfinite(cp[14] ) ?(byte)1:(byte)0;;
160	cp[15] = isfinite(cp[15] ) ?(byte)1:(byte)0;;
161	cp[16] = isfinite(cp[16] ) ?(byte)1:(byte)0;;
162	cp[17] = isfinite(cp[17] ) ?(byte)1:(byte)0;;
163	cp[18] = isfinite(cp[18] ) ?(byte)1:(byte)0;;
164	cp[19] = isfinite(cp[19] ) ?(byte)1:(byte)0;;
165	cp[20] = isfinite(cp[20] ) ?(byte)1:(byte)0;;
166	cp+=21; len -= 21;
167	}
168	while (len-- > 0) {
169	cp = isfinite(cp ) ?(byte)1:(byte)0;;
170	cp++;
171	}
172	} else {
173	double* ap = ((double*)range.Item3 + range.Item1);
174	while (len > 20) {
175	cp[0] = isfinite(ap[0] ) ?(byte)1:(byte)0;;
176	cp[1] = isfinite(ap[1] ) ?(byte)1:(byte)0;;
177	cp[2] = isfinite(ap[2] ) ?(byte)1:(byte)0;;
178	cp[3] = isfinite(ap[3] ) ?(byte)1:(byte)0;;
179	cp[4] = isfinite(ap[4] ) ?(byte)1:(byte)0;;
180	cp[5] = isfinite(ap[5] ) ?(byte)1:(byte)0;;
181	cp[6] = isfinite(ap[6] ) ?(byte)1:(byte)0;;
182	cp[7] = isfinite(ap[7] ) ?(byte)1:(byte)0;;
183	cp[8] = isfinite(ap[8] ) ?(byte)1:(byte)0;;
184	cp[9] = isfinite(ap[9] ) ?(byte)1:(byte)0;;
185	cp[10] = isfinite(ap[10] ) ?(byte)1:(byte)0;;
186	cp[11] = isfinite(ap[11] ) ?(byte)1:(byte)0;;
187	cp[12] = isfinite(ap[12] ) ?(byte)1:(byte)0;;
188	cp[13] = isfinite(ap[13] ) ?(byte)1:(byte)0;;
189	cp[14] = isfinite(ap[14] ) ?(byte)1:(byte)0;;
190	cp[15] = isfinite(ap[15] ) ?(byte)1:(byte)0;;
191	cp[16] = isfinite(ap[16] ) ?(byte)1:(byte)0;;
192	cp[17] = isfinite(ap[17] ) ?(byte)1:(byte)0;;
193	cp[18] = isfinite(ap[18] ) ?(byte)1:(byte)0;;
194	cp[19] = isfinite(ap[19] ) ?(byte)1:(byte)0;;
195	cp[20] = isfinite(ap[20] ) ?(byte)1:(byte)0;;
196	ap += 21;
197	cp += 21;
198	len -= 21;
199	}
200	while (len-- > 0) {
201	cp = isfinite(ap ) ?(byte)1:(byte)0;;
202	ap++;
203	cp++;
204	}
205	}
206	System.Threading.Interlocked.Decrement(ref workerCount);
207	};
208
209	fixed ( double* arrAP = arrA)
210	fixed ( byte* retArrP = retArr) {
211	for (; i < workItemCount - 1; i++) {
212	Tuple<int, int, IntPtr, IntPtr, bool> range
213	= new Tuple<int, int, IntPtr, IntPtr, bool>
214	(i * workItemLength, workItemLength, (IntPtr)arrAP, (IntPtr)retArrP, inplace);
215	System.Threading.Interlocked.Increment(ref workerCount);
216	ILThreadPool.QueueUserWorkItem(i,worker, range);
217	}
218	// the last (or may the only) chunk is done right here
219	worker(new Tuple<int, int, IntPtr, IntPtr, bool>
220	(i * workItemLength, outLen - i * workItemLength, (IntPtr)arrAP, (IntPtr)retArrP, inplace));
221
222	ILThreadPool.Wait4Workers(ref workerCount);
223	}
224	return new ILRetLogical(retStorage);
225	}
226	}
227	/// <summary>Finds finite value elements</summary>
228	/// <param name="A">Input array</param>
229	/// <returns>Logical array with 1 if the corresponding elements of input array is finite, 0 else.</returns>
230	/// <remarks><para>If the input array is empty, an empty array will be returned.</para>
231	/// <para>The array returned will be a dense array.</para></remarks>
232	public unsafe static ILRetLogical isfinite (ILInArray< float > A) {
233	using (ILScope.Enter(A)) {
234	if (A.IsEmpty)
235	return new ILRetLogical(A.Size);
236	ILSize inDim = A.Size;
237	float[] arrA = A.GetArrayForRead();
238	byte [] retArr;
239	int outLen = inDim.NumberOfElements;
240	bool inplace = true;
241
242	if (true){
243	retArr = ILMemoryPool.Pool.New<byte>(outLen);
244	inplace = false;
245	}
246	int i = 0, workItemCount = Settings.s_maxNumberThreads, workItemLength, workerCount = 1;
247	if (Settings.s_maxNumberThreads > 1 && outLen / 2 > Settings.s_minParallelElement1Count) {
248	if (outLen / workItemCount > Settings.s_minParallelElement1Count) {
249	workItemLength = outLen / workItemCount;
250	//workItemLength = (int)((double)outLen / workItemCount * 1.05);
251	} else {
252	workItemLength = outLen / 2;
253	workItemCount = 2;
254	}
255	} else {
256	workItemLength = outLen;
257	workItemCount = 1;
258	}
259	ILDenseStorage<byte> retStorage = new ILDenseStorage<byte>(retArr, inDim);
260
261	Action<object> worker = data => {
262	Tuple<int, int, IntPtr, IntPtr, bool> range = (Tuple<int, int, IntPtr, IntPtr, bool>)data;
263
264	byte* cp = ((byte*)range.Item4 + range.Item1);
265	int len = range.Item2;
266	if (range.Item5) {
267	// inplace
268	while (len > 20) {
269	cp[0] = isfinite(cp[0] ) ?(byte)1:(byte)0;;
270	cp[1] = isfinite(cp[1] ) ?(byte)1:(byte)0;;
271	cp[2] = isfinite(cp[2] ) ?(byte)1:(byte)0;;
272	cp[3] = isfinite(cp[3] ) ?(byte)1:(byte)0;;
273	cp[4] = isfinite(cp[4] ) ?(byte)1:(byte)0;;
274	cp[5] = isfinite(cp[5] ) ?(byte)1:(byte)0;;
275	cp[6] = isfinite(cp[6] ) ?(byte)1:(byte)0;;
276	cp[7] = isfinite(cp[7] ) ?(byte)1:(byte)0;;
277	cp[8] = isfinite(cp[8] ) ?(byte)1:(byte)0;;
278	cp[9] = isfinite(cp[9] ) ?(byte)1:(byte)0;;
279	cp[10] = isfinite(cp[10] ) ?(byte)1:(byte)0;;
280	cp[11] = isfinite(cp[11] ) ?(byte)1:(byte)0;;
281	cp[12] = isfinite(cp[12] ) ?(byte)1:(byte)0;;
282	cp[13] = isfinite(cp[13] ) ?(byte)1:(byte)0;;
283	cp[14] = isfinite(cp[14] ) ?(byte)1:(byte)0;;
284	cp[15] = isfinite(cp[15] ) ?(byte)1:(byte)0;;
285	cp[16] = isfinite(cp[16] ) ?(byte)1:(byte)0;;
286	cp[17] = isfinite(cp[17] ) ?(byte)1:(byte)0;;
287	cp[18] = isfinite(cp[18] ) ?(byte)1:(byte)0;;
288	cp[19] = isfinite(cp[19] ) ?(byte)1:(byte)0;;
289	cp[20] = isfinite(cp[20] ) ?(byte)1:(byte)0;;
290	cp+=21; len -= 21;
291	}
292	while (len-- > 0) {
293	cp = isfinite(cp ) ?(byte)1:(byte)0;;
294	cp++;
295	}
296	} else {
297	float* ap = ((float*)range.Item3 + range.Item1);
298	while (len > 20) {
299	cp[0] = isfinite(ap[0] ) ?(byte)1:(byte)0;;
300	cp[1] = isfinite(ap[1] ) ?(byte)1:(byte)0;;
301	cp[2] = isfinite(ap[2] ) ?(byte)1:(byte)0;;
302	cp[3] = isfinite(ap[3] ) ?(byte)1:(byte)0;;
303	cp[4] = isfinite(ap[4] ) ?(byte)1:(byte)0;;
304	cp[5] = isfinite(ap[5] ) ?(byte)1:(byte)0;;
305	cp[6] = isfinite(ap[6] ) ?(byte)1:(byte)0;;
306	cp[7] = isfinite(ap[7] ) ?(byte)1:(byte)0;;
307	cp[8] = isfinite(ap[8] ) ?(byte)1:(byte)0;;
308	cp[9] = isfinite(ap[9] ) ?(byte)1:(byte)0;;
309	cp[10] = isfinite(ap[10] ) ?(byte)1:(byte)0;;
310	cp[11] = isfinite(ap[11] ) ?(byte)1:(byte)0;;
311	cp[12] = isfinite(ap[12] ) ?(byte)1:(byte)0;;
312	cp[13] = isfinite(ap[13] ) ?(byte)1:(byte)0;;
313	cp[14] = isfinite(ap[14] ) ?(byte)1:(byte)0;;
314	cp[15] = isfinite(ap[15] ) ?(byte)1:(byte)0;;
315	cp[16] = isfinite(ap[16] ) ?(byte)1:(byte)0;;
316	cp[17] = isfinite(ap[17] ) ?(byte)1:(byte)0;;
317	cp[18] = isfinite(ap[18] ) ?(byte)1:(byte)0;;
318	cp[19] = isfinite(ap[19] ) ?(byte)1:(byte)0;;
319	cp[20] = isfinite(ap[20] ) ?(byte)1:(byte)0;;
320	ap += 21;
321	cp += 21;
322	len -= 21;
323	}
324	while (len-- > 0) {
325	cp = isfinite(ap ) ?(byte)1:(byte)0;;
326	ap++;
327	cp++;
328	}
329	}
330	System.Threading.Interlocked.Decrement(ref workerCount);
331	};
332
333	fixed ( float* arrAP = arrA)
334	fixed ( byte* retArrP = retArr) {
335	for (; i < workItemCount - 1; i++) {
336	Tuple<int, int, IntPtr, IntPtr, bool> range
337	= new Tuple<int, int, IntPtr, IntPtr, bool>
338	(i * workItemLength, workItemLength, (IntPtr)arrAP, (IntPtr)retArrP, inplace);
339	System.Threading.Interlocked.Increment(ref workerCount);
340	ILThreadPool.QueueUserWorkItem(i,worker, range);
341	}
342	// the last (or may the only) chunk is done right here
343	worker(new Tuple<int, int, IntPtr, IntPtr, bool>
344	(i * workItemLength, outLen - i * workItemLength, (IntPtr)arrAP, (IntPtr)retArrP, inplace));
345
346	ILThreadPool.Wait4Workers(ref workerCount);
347	}
348	return new ILRetLogical(retStorage);
349	}
350	}
351	/// <summary>Finds finite value elements</summary>
352	/// <param name="A">Input array</param>
353	/// <returns>Logical array with 1 if the corresponding elements of input array is finite, 0 else.</returns>
354	/// <remarks><para>If the input array is empty, an empty array will be returned.</para>
355	/// <para>The array returned will be a dense array.</para></remarks>
356	public unsafe static ILRetLogical isfinite (ILInArray< fcomplex > A) {
357	using (ILScope.Enter(A)) {
358	if (A.IsEmpty)
359	return new ILRetLogical(A.Size);
360	ILSize inDim = A.Size;
361	fcomplex[] arrA = A.GetArrayForRead();
362	byte [] retArr;
363	int outLen = inDim.NumberOfElements;
364	bool inplace = true;
365
366	if (true){
367	retArr = ILMemoryPool.Pool.New<byte>(outLen);
368	inplace = false;
369	}
370	int i = 0, workItemCount = Settings.s_maxNumberThreads, workItemLength, workerCount = 1;
371	if (Settings.s_maxNumberThreads > 1 && outLen / 2 > Settings.s_minParallelElement1Count) {
372	if (outLen / workItemCount > Settings.s_minParallelElement1Count) {
373	workItemLength = outLen / workItemCount;
374	//workItemLength = (int)((double)outLen / workItemCount * 1.05);
375	} else {
376	workItemLength = outLen / 2;
377	workItemCount = 2;
378	}
379	} else {
380	workItemLength = outLen;
381	workItemCount = 1;
382	}
383	ILDenseStorage<byte> retStorage = new ILDenseStorage<byte>(retArr, inDim);
384
385	Action<object> worker = data => {
386	Tuple<int, int, IntPtr, IntPtr, bool> range = (Tuple<int, int, IntPtr, IntPtr, bool>)data;
387
388	byte* cp = ((byte*)range.Item4 + range.Item1);
389	int len = range.Item2;
390	if (range.Item5) {
391	// inplace
392	while (len > 20) {
393	cp[0] = fcomplex.IsFinite(cp[0] ) ?(byte)1:(byte)0;;
394	cp[1] = fcomplex.IsFinite(cp[1] ) ?(byte)1:(byte)0;;
395	cp[2] = fcomplex.IsFinite(cp[2] ) ?(byte)1:(byte)0;;
396	cp[3] = fcomplex.IsFinite(cp[3] ) ?(byte)1:(byte)0;;
397	cp[4] = fcomplex.IsFinite(cp[4] ) ?(byte)1:(byte)0;;
398	cp[5] = fcomplex.IsFinite(cp[5] ) ?(byte)1:(byte)0;;
399	cp[6] = fcomplex.IsFinite(cp[6] ) ?(byte)1:(byte)0;;
400	cp[7] = fcomplex.IsFinite(cp[7] ) ?(byte)1:(byte)0;;
401	cp[8] = fcomplex.IsFinite(cp[8] ) ?(byte)1:(byte)0;;
402	cp[9] = fcomplex.IsFinite(cp[9] ) ?(byte)1:(byte)0;;
403	cp[10] = fcomplex.IsFinite(cp[10] ) ?(byte)1:(byte)0;;
404	cp[11] = fcomplex.IsFinite(cp[11] ) ?(byte)1:(byte)0;;
405	cp[12] = fcomplex.IsFinite(cp[12] ) ?(byte)1:(byte)0;;
406	cp[13] = fcomplex.IsFinite(cp[13] ) ?(byte)1:(byte)0;;
407	cp[14] = fcomplex.IsFinite(cp[14] ) ?(byte)1:(byte)0;;
408	cp[15] = fcomplex.IsFinite(cp[15] ) ?(byte)1:(byte)0;;
409	cp[16] = fcomplex.IsFinite(cp[16] ) ?(byte)1:(byte)0;;
410	cp[17] = fcomplex.IsFinite(cp[17] ) ?(byte)1:(byte)0;;
411	cp[18] = fcomplex.IsFinite(cp[18] ) ?(byte)1:(byte)0;;
412	cp[19] = fcomplex.IsFinite(cp[19] ) ?(byte)1:(byte)0;;
413	cp[20] = fcomplex.IsFinite(cp[20] ) ?(byte)1:(byte)0;;
414	cp+=21; len -= 21;
415	}
416	while (len-- > 0) {
417	cp = fcomplex.IsFinite(cp ) ?(byte)1:(byte)0;;
418	cp++;
419	}
420	} else {
421	fcomplex* ap = ((fcomplex*)range.Item3 + range.Item1);
422	while (len > 20) {
423	cp[0] = fcomplex.IsFinite(ap[0] ) ?(byte)1:(byte)0;;
424	cp[1] = fcomplex.IsFinite(ap[1] ) ?(byte)1:(byte)0;;
425	cp[2] = fcomplex.IsFinite(ap[2] ) ?(byte)1:(byte)0;;
426	cp[3] = fcomplex.IsFinite(ap[3] ) ?(byte)1:(byte)0;;
427	cp[4] = fcomplex.IsFinite(ap[4] ) ?(byte)1:(byte)0;;
428	cp[5] = fcomplex.IsFinite(ap[5] ) ?(byte)1:(byte)0;;
429	cp[6] = fcomplex.IsFinite(ap[6] ) ?(byte)1:(byte)0;;
430	cp[7] = fcomplex.IsFinite(ap[7] ) ?(byte)1:(byte)0;;
431	cp[8] = fcomplex.IsFinite(ap[8] ) ?(byte)1:(byte)0;;
432	cp[9] = fcomplex.IsFinite(ap[9] ) ?(byte)1:(byte)0;;
433	cp[10] = fcomplex.IsFinite(ap[10] ) ?(byte)1:(byte)0;;
434	cp[11] = fcomplex.IsFinite(ap[11] ) ?(byte)1:(byte)0;;
435	cp[12] = fcomplex.IsFinite(ap[12] ) ?(byte)1:(byte)0;;
436	cp[13] = fcomplex.IsFinite(ap[13] ) ?(byte)1:(byte)0;;
437	cp[14] = fcomplex.IsFinite(ap[14] ) ?(byte)1:(byte)0;;
438	cp[15] = fcomplex.IsFinite(ap[15] ) ?(byte)1:(byte)0;;
439	cp[16] = fcomplex.IsFinite(ap[16] ) ?(byte)1:(byte)0;;
440	cp[17] = fcomplex.IsFinite(ap[17] ) ?(byte)1:(byte)0;;
441	cp[18] = fcomplex.IsFinite(ap[18] ) ?(byte)1:(byte)0;;
442	cp[19] = fcomplex.IsFinite(ap[19] ) ?(byte)1:(byte)0;;
443	cp[20] = fcomplex.IsFinite(ap[20] ) ?(byte)1:(byte)0;;
444	ap += 21;
445	cp += 21;
446	len -= 21;
447	}
448	while (len-- > 0) {
449	cp = fcomplex.IsFinite(ap ) ?(byte)1:(byte)0;;
450	ap++;
451	cp++;
452	}
453	}
454	System.Threading.Interlocked.Decrement(ref workerCount);
455	};
456
457	fixed ( fcomplex* arrAP = arrA)
458	fixed ( byte* retArrP = retArr) {
459	for (; i < workItemCount - 1; i++) {
460	Tuple<int, int, IntPtr, IntPtr, bool> range
461	= new Tuple<int, int, IntPtr, IntPtr, bool>
462	(i * workItemLength, workItemLength, (IntPtr)arrAP, (IntPtr)retArrP, inplace);
463	System.Threading.Interlocked.Increment(ref workerCount);
464	ILThreadPool.QueueUserWorkItem(i,worker, range);
465	}
466	// the last (or may the only) chunk is done right here
467	worker(new Tuple<int, int, IntPtr, IntPtr, bool>
468	(i * workItemLength, outLen - i * workItemLength, (IntPtr)arrAP, (IntPtr)retArrP, inplace));
469
470	ILThreadPool.Wait4Workers(ref workerCount);
471	}
472	return new ILRetLogical(retStorage);
473	}
474	}
475	/// <summary>Finds finite value elements</summary>
476	/// <param name="A">Input array</param>
477	/// <returns>Logical array with 1 if the corresponding elements of input array is finite, 0 else.</returns>
478	/// <remarks><para>If the input array is empty, an empty array will be returned.</para>
479	/// <para>The array returned will be a dense array.</para></remarks>
480	public unsafe static ILRetLogical isfinite (ILInArray< complex > A) {
481	using (ILScope.Enter(A)) {
482	if (A.IsEmpty)
483	return new ILRetLogical(A.Size);
484	ILSize inDim = A.Size;
485	complex[] arrA = A.GetArrayForRead();
486	byte [] retArr;
487	int outLen = inDim.NumberOfElements;
488	bool inplace = true;
489
490	if (true){
491	retArr = ILMemoryPool.Pool.New<byte>(outLen);
492	inplace = false;
493	}
494	int i = 0, workItemCount = Settings.s_maxNumberThreads, workItemLength, workerCount = 1;
495	if (Settings.s_maxNumberThreads > 1 && outLen / 2 > Settings.s_minParallelElement1Count) {
496	if (outLen / workItemCount > Settings.s_minParallelElement1Count) {
497	workItemLength = outLen / workItemCount;
498	//workItemLength = (int)((double)outLen / workItemCount * 1.05);
499	} else {
500	workItemLength = outLen / 2;
501	workItemCount = 2;
502	}
503	} else {
504	workItemLength = outLen;
505	workItemCount = 1;
506	}
507	ILDenseStorage<byte> retStorage = new ILDenseStorage<byte>(retArr, inDim);
508
509	Action<object> worker = data => {
510	Tuple<int, int, IntPtr, IntPtr, bool> range = (Tuple<int, int, IntPtr, IntPtr, bool>)data;
511
512	byte* cp = ((byte*)range.Item4 + range.Item1);
513	int len = range.Item2;
514	if (range.Item5) {
515	// inplace
516	while (len > 20) {
517	cp[0] = complex.IsFinite(cp[0] ) ?(byte)1:(byte)0;;
518	cp[1] = complex.IsFinite(cp[1] ) ?(byte)1:(byte)0;;
519	cp[2] = complex.IsFinite(cp[2] ) ?(byte)1:(byte)0;;
520	cp[3] = complex.IsFinite(cp[3] ) ?(byte)1:(byte)0;;
521	cp[4] = complex.IsFinite(cp[4] ) ?(byte)1:(byte)0;;
522	cp[5] = complex.IsFinite(cp[5] ) ?(byte)1:(byte)0;;
523	cp[6] = complex.IsFinite(cp[6] ) ?(byte)1:(byte)0;;
524	cp[7] = complex.IsFinite(cp[7] ) ?(byte)1:(byte)0;;
525	cp[8] = complex.IsFinite(cp[8] ) ?(byte)1:(byte)0;;
526	cp[9] = complex.IsFinite(cp[9] ) ?(byte)1:(byte)0;;
527	cp[10] = complex.IsFinite(cp[10] ) ?(byte)1:(byte)0;;
528	cp[11] = complex.IsFinite(cp[11] ) ?(byte)1:(byte)0;;
529	cp[12] = complex.IsFinite(cp[12] ) ?(byte)1:(byte)0;;
530	cp[13] = complex.IsFinite(cp[13] ) ?(byte)1:(byte)0;;
531	cp[14] = complex.IsFinite(cp[14] ) ?(byte)1:(byte)0;;
532	cp[15] = complex.IsFinite(cp[15] ) ?(byte)1:(byte)0;;
533	cp[16] = complex.IsFinite(cp[16] ) ?(byte)1:(byte)0;;
534	cp[17] = complex.IsFinite(cp[17] ) ?(byte)1:(byte)0;;
535	cp[18] = complex.IsFinite(cp[18] ) ?(byte)1:(byte)0;;
536	cp[19] = complex.IsFinite(cp[19] ) ?(byte)1:(byte)0;;
537	cp[20] = complex.IsFinite(cp[20] ) ?(byte)1:(byte)0;;
538	cp+=21; len -= 21;
539	}
540	while (len-- > 0) {
541	cp = complex.IsFinite(cp ) ?(byte)1:(byte)0;;
542	cp++;
543	}
544	} else {
545	complex* ap = ((complex*)range.Item3 + range.Item1);
546	while (len > 20) {
547	cp[0] = complex.IsFinite(ap[0] ) ?(byte)1:(byte)0;;
548	cp[1] = complex.IsFinite(ap[1] ) ?(byte)1:(byte)0;;
549	cp[2] = complex.IsFinite(ap[2] ) ?(byte)1:(byte)0;;
550	cp[3] = complex.IsFinite(ap[3] ) ?(byte)1:(byte)0;;
551	cp[4] = complex.IsFinite(ap[4] ) ?(byte)1:(byte)0;;
552	cp[5] = complex.IsFinite(ap[5] ) ?(byte)1:(byte)0;;
553	cp[6] = complex.IsFinite(ap[6] ) ?(byte)1:(byte)0;;
554	cp[7] = complex.IsFinite(ap[7] ) ?(byte)1:(byte)0;;
555	cp[8] = complex.IsFinite(ap[8] ) ?(byte)1:(byte)0;;
556	cp[9] = complex.IsFinite(ap[9] ) ?(byte)1:(byte)0;;
557	cp[10] = complex.IsFinite(ap[10] ) ?(byte)1:(byte)0;;
558	cp[11] = complex.IsFinite(ap[11] ) ?(byte)1:(byte)0;;
559	cp[12] = complex.IsFinite(ap[12] ) ?(byte)1:(byte)0;;
560	cp[13] = complex.IsFinite(ap[13] ) ?(byte)1:(byte)0;;
561	cp[14] = complex.IsFinite(ap[14] ) ?(byte)1:(byte)0;;
562	cp[15] = complex.IsFinite(ap[15] ) ?(byte)1:(byte)0;;
563	cp[16] = complex.IsFinite(ap[16] ) ?(byte)1:(byte)0;;
564	cp[17] = complex.IsFinite(ap[17] ) ?(byte)1:(byte)0;;
565	cp[18] = complex.IsFinite(ap[18] ) ?(byte)1:(byte)0;;
566	cp[19] = complex.IsFinite(ap[19] ) ?(byte)1:(byte)0;;
567	cp[20] = complex.IsFinite(ap[20] ) ?(byte)1:(byte)0;;
568	ap += 21;
569	cp += 21;
570	len -= 21;
571	}
572	while (len-- > 0) {
573	cp = complex.IsFinite(ap ) ?(byte)1:(byte)0;;
574	ap++;
575	cp++;
576	}
577	}
578	System.Threading.Interlocked.Decrement(ref workerCount);
579	};
580
581	fixed ( complex* arrAP = arrA)
582	fixed ( byte* retArrP = retArr) {
583	for (; i < workItemCount - 1; i++) {
584	Tuple<int, int, IntPtr, IntPtr, bool> range
585	= new Tuple<int, int, IntPtr, IntPtr, bool>
586	(i * workItemLength, workItemLength, (IntPtr)arrAP, (IntPtr)retArrP, inplace);
587	System.Threading.Interlocked.Increment(ref workerCount);
588	ILThreadPool.QueueUserWorkItem(i,worker, range);
589	}
590	// the last (or may the only) chunk is done right here
591	worker(new Tuple<int, int, IntPtr, IntPtr, bool>
592	(i * workItemLength, outLen - i * workItemLength, (IntPtr)arrAP, (IntPtr)retArrP, inplace));
593
594	ILThreadPool.Wait4Workers(ref workerCount);
595	}
596	return new ILRetLogical(retStorage);
597	}
598	}
599
600	#endregion HYCALPER AUTO GENERATED CODE
601
602	}
603	}

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