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source: code/trunk/src/external/bullet/BulletCollision/Gimpact/gim_linear_math.h @ 5738

Last change on this file since 5738 was 5738, checked in by landauf, 15 years ago
merged libraries2 back to trunk
Property svn:eol-style set to `native`
File size: 37.1 KB

Line
1	#ifndef GIM_LINEAR_H_INCLUDED
2	#define GIM_LINEAR_H_INCLUDED
3
4	/*! \file gim_linear_math.h
5	*\author Francisco Len Nßjera
6	Type Independant Vector and matrix operations.
7	*/
8	/*
9	-----------------------------------------------------------------------------
10	This source file is part of GIMPACT Library.
11
12	For the latest info, see http://gimpact.sourceforge.net/
13
14	Copyright (c) 2006 Francisco Leon Najera. C.C. 80087371.
15	email: projectileman@yahoo.com
16
17	This library is free software; you can redistribute it and/or
18	modify it under the terms of EITHER:
19	(1) The GNU Lesser General Public License as published by the Free
20	Software Foundation; either version 2.1 of the License, or (at
21	your option) any later version. The text of the GNU Lesser
22	General Public License is included with this library in the
23	file GIMPACT-LICENSE-LGPL.TXT.
24	(2) The BSD-style license that is included with this library in
25	the file GIMPACT-LICENSE-BSD.TXT.
26	(3) The zlib/libpng license that is included with this library in
27	the file GIMPACT-LICENSE-ZLIB.TXT.
28
29	This library is distributed in the hope that it will be useful,
30	but WITHOUT ANY WARRANTY; without even the implied warranty of
31	MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the files
32	GIMPACT-LICENSE-LGPL.TXT, GIMPACT-LICENSE-ZLIB.TXT and GIMPACT-LICENSE-BSD.TXT for more details.
33
34	-----------------------------------------------------------------------------
35	*/
36
37
38	#include "gim_math.h"
39	#include "gim_geom_types.h"
40
41
42
43
44	//! Zero out a 2D vector
45	#define VEC_ZERO_2(a) \
46	{ \
47	(a)[0] = (a)[1] = 0.0f; \
48	}\
49
50
51	//! Zero out a 3D vector
52	#define VEC_ZERO(a) \
53	{ \
54	(a)[0] = (a)[1] = (a)[2] = 0.0f; \
55	}\
56
57
58	/// Zero out a 4D vector
59	#define VEC_ZERO_4(a) \
60	{ \
61	(a)[0] = (a)[1] = (a)[2] = (a)[3] = 0.0f; \
62	}\
63
64
65	/// Vector copy
66	#define VEC_COPY_2(b,a) \
67	{ \
68	(b)[0] = (a)[0]; \
69	(b)[1] = (a)[1]; \
70	}\
71
72
73	/// Copy 3D vector
74	#define VEC_COPY(b,a) \
75	{ \
76	(b)[0] = (a)[0]; \
77	(b)[1] = (a)[1]; \
78	(b)[2] = (a)[2]; \
79	}\
80
81
82	/// Copy 4D vector
83	#define VEC_COPY_4(b,a) \
84	{ \
85	(b)[0] = (a)[0]; \
86	(b)[1] = (a)[1]; \
87	(b)[2] = (a)[2]; \
88	(b)[3] = (a)[3]; \
89	}\
90
91	/// VECTOR SWAP
92	#define VEC_SWAP(b,a) \
93	{ \
94	GIM_SWAP_NUMBERS((b)[0],(a)[0]);\
95	GIM_SWAP_NUMBERS((b)[1],(a)[1]);\
96	GIM_SWAP_NUMBERS((b)[2],(a)[2]);\
97	}\
98
99	/// Vector difference
100	#define VEC_DIFF_2(v21,v2,v1) \
101	{ \
102	(v21)[0] = (v2)[0] - (v1)[0]; \
103	(v21)[1] = (v2)[1] - (v1)[1]; \
104	}\
105
106
107	/// Vector difference
108	#define VEC_DIFF(v21,v2,v1) \
109	{ \
110	(v21)[0] = (v2)[0] - (v1)[0]; \
111	(v21)[1] = (v2)[1] - (v1)[1]; \
112	(v21)[2] = (v2)[2] - (v1)[2]; \
113	}\
114
115
116	/// Vector difference
117	#define VEC_DIFF_4(v21,v2,v1) \
118	{ \
119	(v21)[0] = (v2)[0] - (v1)[0]; \
120	(v21)[1] = (v2)[1] - (v1)[1]; \
121	(v21)[2] = (v2)[2] - (v1)[2]; \
122	(v21)[3] = (v2)[3] - (v1)[3]; \
123	}\
124
125
126	/// Vector sum
127	#define VEC_SUM_2(v21,v2,v1) \
128	{ \
129	(v21)[0] = (v2)[0] + (v1)[0]; \
130	(v21)[1] = (v2)[1] + (v1)[1]; \
131	}\
132
133
134	/// Vector sum
135	#define VEC_SUM(v21,v2,v1) \
136	{ \
137	(v21)[0] = (v2)[0] + (v1)[0]; \
138	(v21)[1] = (v2)[1] + (v1)[1]; \
139	(v21)[2] = (v2)[2] + (v1)[2]; \
140	}\
141
142
143	/// Vector sum
144	#define VEC_SUM_4(v21,v2,v1) \
145	{ \
146	(v21)[0] = (v2)[0] + (v1)[0]; \
147	(v21)[1] = (v2)[1] + (v1)[1]; \
148	(v21)[2] = (v2)[2] + (v1)[2]; \
149	(v21)[3] = (v2)[3] + (v1)[3]; \
150	}\
151
152
153	/// scalar times vector
154	#define VEC_SCALE_2(c,a,b) \
155	{ \
156	(c)[0] = (a)*(b)[0]; \
157	(c)[1] = (a)*(b)[1]; \
158	}\
159
160
161	/// scalar times vector
162	#define VEC_SCALE(c,a,b) \
163	{ \
164	(c)[0] = (a)*(b)[0]; \
165	(c)[1] = (a)*(b)[1]; \
166	(c)[2] = (a)*(b)[2]; \
167	}\
168
169
170	/// scalar times vector
171	#define VEC_SCALE_4(c,a,b) \
172	{ \
173	(c)[0] = (a)*(b)[0]; \
174	(c)[1] = (a)*(b)[1]; \
175	(c)[2] = (a)*(b)[2]; \
176	(c)[3] = (a)*(b)[3]; \
177	}\
178
179
180	/// accumulate scaled vector
181	#define VEC_ACCUM_2(c,a,b) \
182	{ \
183	(c)[0] += (a)*(b)[0]; \
184	(c)[1] += (a)*(b)[1]; \
185	}\
186
187
188	/// accumulate scaled vector
189	#define VEC_ACCUM(c,a,b) \
190	{ \
191	(c)[0] += (a)*(b)[0]; \
192	(c)[1] += (a)*(b)[1]; \
193	(c)[2] += (a)*(b)[2]; \
194	}\
195
196
197	/// accumulate scaled vector
198	#define VEC_ACCUM_4(c,a,b) \
199	{ \
200	(c)[0] += (a)*(b)[0]; \
201	(c)[1] += (a)*(b)[1]; \
202	(c)[2] += (a)*(b)[2]; \
203	(c)[3] += (a)*(b)[3]; \
204	}\
205
206
207	/// Vector dot product
208	#define VEC_DOT_2(a,b) ((a)[0](b)[0] + (a)[1](b)[1])
209
210
211	/// Vector dot product
212	#define VEC_DOT(a,b) ((a)[0](b)[0] + (a)[1](b)[1] + (a)[2]*(b)[2])
213
214	/// Vector dot product
215	#define VEC_DOT_4(a,b) ((a)[0](b)[0] + (a)[1](b)[1] + (a)[2](b)[2] + (a)[3](b)[3])
216
217	/// vector impact parameter (squared)
218	#define VEC_IMPACT_SQ(bsq,direction,position) {\
219	GREAL _llel_ = VEC_DOT(direction, position);\
220	bsq = VEC_DOT(position, position) - _llel_*_llel_;\
221	}\
222
223
224	/// vector impact parameter
225	#define VEC_IMPACT(bsq,direction,position) {\
226	VEC_IMPACT_SQ(bsq,direction,position); \
227	GIM_SQRT(bsq,bsq); \
228	}\
229
230	/// Vector length
231	#define VEC_LENGTH_2(a,l)\
232	{\
233	GREAL _pp = VEC_DOT_2(a,a);\
234	GIM_SQRT(_pp,l);\
235	}\
236
237
238	/// Vector length
239	#define VEC_LENGTH(a,l)\
240	{\
241	GREAL _pp = VEC_DOT(a,a);\
242	GIM_SQRT(_pp,l);\
243	}\
244
245
246	/// Vector length
247	#define VEC_LENGTH_4(a,l)\
248	{\
249	GREAL _pp = VEC_DOT_4(a,a);\
250	GIM_SQRT(_pp,l);\
251	}\
252
253	/// Vector inv length
254	#define VEC_INV_LENGTH_2(a,l)\
255	{\
256	GREAL _pp = VEC_DOT_2(a,a);\
257	GIM_INV_SQRT(_pp,l);\
258	}\
259
260
261	/// Vector inv length
262	#define VEC_INV_LENGTH(a,l)\
263	{\
264	GREAL _pp = VEC_DOT(a,a);\
265	GIM_INV_SQRT(_pp,l);\
266	}\
267
268
269	/// Vector inv length
270	#define VEC_INV_LENGTH_4(a,l)\
271	{\
272	GREAL _pp = VEC_DOT_4(a,a);\
273	GIM_INV_SQRT(_pp,l);\
274	}\
275
276
277
278	/// distance between two points
279	#define VEC_DISTANCE(_len,_va,_vb) {\
280	vec3f _tmp_; \
281	VEC_DIFF(_tmp_, _vb, _va); \
282	VEC_LENGTH(_tmp_,_len); \
283	}\
284
285
286	/// Vector length
287	#define VEC_CONJUGATE_LENGTH(a,l)\
288	{\
289	GREAL _pp = 1.0 - a[0]a[0] - a[1]a[1] - a[2]*a[2];\
290	GIM_SQRT(_pp,l);\
291	}\
292
293
294	/// Vector length
295	#define VEC_NORMALIZE(a) { \
296	GREAL len;\
297	VEC_INV_LENGTH(a,len); \
298	if(len<G_REAL_INFINITY)\
299	{\
300	a[0] *= len; \
301	a[1] *= len; \
302	a[2] *= len; \
303	} \
304	}\
305
306	/// Set Vector size
307	#define VEC_RENORMALIZE(a,newlen) { \
308	GREAL len;\
309	VEC_INV_LENGTH(a,len); \
310	if(len<G_REAL_INFINITY)\
311	{\
312	len *= newlen;\
313	a[0] *= len; \
314	a[1] *= len; \
315	a[2] *= len; \
316	} \
317	}\
318
319	/// Vector cross
320	#define VEC_CROSS(c,a,b) \
321	{ \
322	c[0] = (a)[1] * (b)[2] - (a)[2] * (b)[1]; \
323	c[1] = (a)[2] * (b)[0] - (a)[0] * (b)[2]; \
324	c[2] = (a)[0] * (b)[1] - (a)[1] * (b)[0]; \
325	}\
326
327
328	/*! Vector perp -- assumes that n is of unit length
329	* accepts vector v, subtracts out any component parallel to n */
330	#define VEC_PERPENDICULAR(vp,v,n) \
331	{ \
332	GREAL dot = VEC_DOT(v, n); \
333	vp[0] = (v)[0] - dot*(n)[0]; \
334	vp[1] = (v)[1] - dot*(n)[1]; \
335	vp[2] = (v)[2] - dot*(n)[2]; \
336	}\
337
338
339	/! Vector parallel -- assumes that n is of unit length /
340	#define VEC_PARALLEL(vp,v,n) \
341	{ \
342	GREAL dot = VEC_DOT(v, n); \
343	vp[0] = (dot) * (n)[0]; \
344	vp[1] = (dot) * (n)[1]; \
345	vp[2] = (dot) * (n)[2]; \
346	}\
347
348	/*! Same as Vector parallel -- n can have any length
349	* accepts vector v, subtracts out any component perpendicular to n */
350	#define VEC_PROJECT(vp,v,n) \
351	{ \
352	GREAL scalar = VEC_DOT(v, n); \
353	scalar/= VEC_DOT(n, n); \
354	vp[0] = (scalar) * (n)[0]; \
355	vp[1] = (scalar) * (n)[1]; \
356	vp[2] = (scalar) * (n)[2]; \
357	}\
358
359
360	/! accepts vector v/
361	#define VEC_UNPROJECT(vp,v,n) \
362	{ \
363	GREAL scalar = VEC_DOT(v, n); \
364	scalar = VEC_DOT(n, n)/scalar; \
365	vp[0] = (scalar) * (n)[0]; \
366	vp[1] = (scalar) * (n)[1]; \
367	vp[2] = (scalar) * (n)[2]; \
368	}\
369
370
371	/*! Vector reflection -- assumes n is of unit length
372	Takes vector v, reflects it against reflector n, and returns vr */
373	#define VEC_REFLECT(vr,v,n) \
374	{ \
375	GREAL dot = VEC_DOT(v, n); \
376	vr[0] = (v)[0] - 2.0 * (dot) * (n)[0]; \
377	vr[1] = (v)[1] - 2.0 * (dot) * (n)[1]; \
378	vr[2] = (v)[2] - 2.0 * (dot) * (n)[2]; \
379	}\
380
381
382	/*! Vector blending
383	Takes two vectors a, b, blends them together with two scalars */
384	#define VEC_BLEND_AB(vr,sa,a,sb,b) \
385	{ \
386	vr[0] = (sa) * (a)[0] + (sb) * (b)[0]; \
387	vr[1] = (sa) * (a)[1] + (sb) * (b)[1]; \
388	vr[2] = (sa) * (a)[2] + (sb) * (b)[2]; \
389	}\
390
391	/*! Vector blending
392	Takes two vectors a, b, blends them together with s <=1 */
393	#define VEC_BLEND(vr,a,b,s) VEC_BLEND_AB(vr,(1-s),a,s,b)
394
395	#define VEC_SET3(a,b,op,c) a[0]=b[0] op c[0]; a[1]=b[1] op c[1]; a[2]=b[2] op c[2];
396
397	//! Finds the bigger cartesian coordinate from a vector
398	#define VEC_MAYOR_COORD(vec, maxc)\
399	{\
400	GREAL A[] = {fabs(vec[0]),fabs(vec[1]),fabs(vec[2])};\
401	maxc = A[0]>A[1]?(A[0]>A[2]?0:2):(A[1]>A[2]?1:2);\
402	}\
403
404	//! Finds the 2 smallest cartesian coordinates from a vector
405	#define VEC_MINOR_AXES(vec, i0, i1)\
406	{\
407	VEC_MAYOR_COORD(vec,i0);\
408	i0 = (i0+1)%3;\
409	i1 = (i0+1)%3;\
410	}\
411
412
413
414
415	#define VEC_EQUAL(v1,v2) (v1[0]==v2[0]&&v1[1]==v2[1]&&v1[2]==v2[2])
416
417	#define VEC_NEAR_EQUAL(v1,v2) (GIM_NEAR_EQUAL(v1[0],v2[0])&&GIM_NEAR_EQUAL(v1[1],v2[1])&&GIM_NEAR_EQUAL(v1[2],v2[2]))
418
419
420	/// Vector cross
421	#define X_AXIS_CROSS_VEC(dst,src)\
422	{ \
423	dst[0] = 0.0f; \
424	dst[1] = -src[2]; \
425	dst[2] = src[1]; \
426	}\
427
428	#define Y_AXIS_CROSS_VEC(dst,src)\
429	{ \
430	dst[0] = src[2]; \
431	dst[1] = 0.0f; \
432	dst[2] = -src[0]; \
433	}\
434
435	#define Z_AXIS_CROSS_VEC(dst,src)\
436	{ \
437	dst[0] = -src[1]; \
438	dst[1] = src[0]; \
439	dst[2] = 0.0f; \
440	}\
441
442
443
444
445
446
447	/// initialize matrix
448	#define IDENTIFY_MATRIX_3X3(m) \
449	{ \
450	m[0][0] = 1.0; \
451	m[0][1] = 0.0; \
452	m[0][2] = 0.0; \
453	\
454	m[1][0] = 0.0; \
455	m[1][1] = 1.0; \
456	m[1][2] = 0.0; \
457	\
458	m[2][0] = 0.0; \
459	m[2][1] = 0.0; \
460	m[2][2] = 1.0; \
461	}\
462
463	/! initialize matrix /
464	#define IDENTIFY_MATRIX_4X4(m) \
465	{ \
466	m[0][0] = 1.0; \
467	m[0][1] = 0.0; \
468	m[0][2] = 0.0; \
469	m[0][3] = 0.0; \
470	\
471	m[1][0] = 0.0; \
472	m[1][1] = 1.0; \
473	m[1][2] = 0.0; \
474	m[1][3] = 0.0; \
475	\
476	m[2][0] = 0.0; \
477	m[2][1] = 0.0; \
478	m[2][2] = 1.0; \
479	m[2][3] = 0.0; \
480	\
481	m[3][0] = 0.0; \
482	m[3][1] = 0.0; \
483	m[3][2] = 0.0; \
484	m[3][3] = 1.0; \
485	}\
486
487	/! initialize matrix /
488	#define ZERO_MATRIX_4X4(m) \
489	{ \
490	m[0][0] = 0.0; \
491	m[0][1] = 0.0; \
492	m[0][2] = 0.0; \
493	m[0][3] = 0.0; \
494	\
495	m[1][0] = 0.0; \
496	m[1][1] = 0.0; \
497	m[1][2] = 0.0; \
498	m[1][3] = 0.0; \
499	\
500	m[2][0] = 0.0; \
501	m[2][1] = 0.0; \
502	m[2][2] = 0.0; \
503	m[2][3] = 0.0; \
504	\
505	m[3][0] = 0.0; \
506	m[3][1] = 0.0; \
507	m[3][2] = 0.0; \
508	m[3][3] = 0.0; \
509	}\
510
511	/! matrix rotation X /
512	#define ROTX_CS(m,cosine,sine) \
513	{ \
514	/* rotation about the x-axis */ \
515	\
516	m[0][0] = 1.0; \
517	m[0][1] = 0.0; \
518	m[0][2] = 0.0; \
519	m[0][3] = 0.0; \
520	\
521	m[1][0] = 0.0; \
522	m[1][1] = (cosine); \
523	m[1][2] = (sine); \
524	m[1][3] = 0.0; \
525	\
526	m[2][0] = 0.0; \
527	m[2][1] = -(sine); \
528	m[2][2] = (cosine); \
529	m[2][3] = 0.0; \
530	\
531	m[3][0] = 0.0; \
532	m[3][1] = 0.0; \
533	m[3][2] = 0.0; \
534	m[3][3] = 1.0; \
535	}\
536
537	/! matrix rotation Y /
538	#define ROTY_CS(m,cosine,sine) \
539	{ \
540	/* rotation about the y-axis */ \
541	\
542	m[0][0] = (cosine); \
543	m[0][1] = 0.0; \
544	m[0][2] = -(sine); \
545	m[0][3] = 0.0; \
546	\
547	m[1][0] = 0.0; \
548	m[1][1] = 1.0; \
549	m[1][2] = 0.0; \
550	m[1][3] = 0.0; \
551	\
552	m[2][0] = (sine); \
553	m[2][1] = 0.0; \
554	m[2][2] = (cosine); \
555	m[2][3] = 0.0; \
556	\
557	m[3][0] = 0.0; \
558	m[3][1] = 0.0; \
559	m[3][2] = 0.0; \
560	m[3][3] = 1.0; \
561	}\
562
563	/! matrix rotation Z /
564	#define ROTZ_CS(m,cosine,sine) \
565	{ \
566	/* rotation about the z-axis */ \
567	\
568	m[0][0] = (cosine); \
569	m[0][1] = (sine); \
570	m[0][2] = 0.0; \
571	m[0][3] = 0.0; \
572	\
573	m[1][0] = -(sine); \
574	m[1][1] = (cosine); \
575	m[1][2] = 0.0; \
576	m[1][3] = 0.0; \
577	\
578	m[2][0] = 0.0; \
579	m[2][1] = 0.0; \
580	m[2][2] = 1.0; \
581	m[2][3] = 0.0; \
582	\
583	m[3][0] = 0.0; \
584	m[3][1] = 0.0; \
585	m[3][2] = 0.0; \
586	m[3][3] = 1.0; \
587	}\
588
589	/! matrix copy /
590	#define COPY_MATRIX_2X2(b,a) \
591	{ \
592	b[0][0] = a[0][0]; \
593	b[0][1] = a[0][1]; \
594	\
595	b[1][0] = a[1][0]; \
596	b[1][1] = a[1][1]; \
597	\
598	}\
599
600
601	/! matrix copy /
602	#define COPY_MATRIX_2X3(b,a) \
603	{ \
604	b[0][0] = a[0][0]; \
605	b[0][1] = a[0][1]; \
606	b[0][2] = a[0][2]; \
607	\
608	b[1][0] = a[1][0]; \
609	b[1][1] = a[1][1]; \
610	b[1][2] = a[1][2]; \
611	}\
612
613
614	/! matrix copy /
615	#define COPY_MATRIX_3X3(b,a) \
616	{ \
617	b[0][0] = a[0][0]; \
618	b[0][1] = a[0][1]; \
619	b[0][2] = a[0][2]; \
620	\
621	b[1][0] = a[1][0]; \
622	b[1][1] = a[1][1]; \
623	b[1][2] = a[1][2]; \
624	\
625	b[2][0] = a[2][0]; \
626	b[2][1] = a[2][1]; \
627	b[2][2] = a[2][2]; \
628	}\
629
630
631	/! matrix copy /
632	#define COPY_MATRIX_4X4(b,a) \
633	{ \
634	b[0][0] = a[0][0]; \
635	b[0][1] = a[0][1]; \
636	b[0][2] = a[0][2]; \
637	b[0][3] = a[0][3]; \
638	\
639	b[1][0] = a[1][0]; \
640	b[1][1] = a[1][1]; \
641	b[1][2] = a[1][2]; \
642	b[1][3] = a[1][3]; \
643	\
644	b[2][0] = a[2][0]; \
645	b[2][1] = a[2][1]; \
646	b[2][2] = a[2][2]; \
647	b[2][3] = a[2][3]; \
648	\
649	b[3][0] = a[3][0]; \
650	b[3][1] = a[3][1]; \
651	b[3][2] = a[3][2]; \
652	b[3][3] = a[3][3]; \
653	}\
654
655
656	/! matrix transpose /
657	#define TRANSPOSE_MATRIX_2X2(b,a) \
658	{ \
659	b[0][0] = a[0][0]; \
660	b[0][1] = a[1][0]; \
661	\
662	b[1][0] = a[0][1]; \
663	b[1][1] = a[1][1]; \
664	}\
665
666
667	/! matrix transpose /
668	#define TRANSPOSE_MATRIX_3X3(b,a) \
669	{ \
670	b[0][0] = a[0][0]; \
671	b[0][1] = a[1][0]; \
672	b[0][2] = a[2][0]; \
673	\
674	b[1][0] = a[0][1]; \
675	b[1][1] = a[1][1]; \
676	b[1][2] = a[2][1]; \
677	\
678	b[2][0] = a[0][2]; \
679	b[2][1] = a[1][2]; \
680	b[2][2] = a[2][2]; \
681	}\
682
683
684	/! matrix transpose /
685	#define TRANSPOSE_MATRIX_4X4(b,a) \
686	{ \
687	b[0][0] = a[0][0]; \
688	b[0][1] = a[1][0]; \
689	b[0][2] = a[2][0]; \
690	b[0][3] = a[3][0]; \
691	\
692	b[1][0] = a[0][1]; \
693	b[1][1] = a[1][1]; \
694	b[1][2] = a[2][1]; \
695	b[1][3] = a[3][1]; \
696	\
697	b[2][0] = a[0][2]; \
698	b[2][1] = a[1][2]; \
699	b[2][2] = a[2][2]; \
700	b[2][3] = a[3][2]; \
701	\
702	b[3][0] = a[0][3]; \
703	b[3][1] = a[1][3]; \
704	b[3][2] = a[2][3]; \
705	b[3][3] = a[3][3]; \
706	}\
707
708
709	/! multiply matrix by scalar /
710	#define SCALE_MATRIX_2X2(b,s,a) \
711	{ \
712	b[0][0] = (s) * a[0][0]; \
713	b[0][1] = (s) * a[0][1]; \
714	\
715	b[1][0] = (s) * a[1][0]; \
716	b[1][1] = (s) * a[1][1]; \
717	}\
718
719
720	/! multiply matrix by scalar /
721	#define SCALE_MATRIX_3X3(b,s,a) \
722	{ \
723	b[0][0] = (s) * a[0][0]; \
724	b[0][1] = (s) * a[0][1]; \
725	b[0][2] = (s) * a[0][2]; \
726	\
727	b[1][0] = (s) * a[1][0]; \
728	b[1][1] = (s) * a[1][1]; \
729	b[1][2] = (s) * a[1][2]; \
730	\
731	b[2][0] = (s) * a[2][0]; \
732	b[2][1] = (s) * a[2][1]; \
733	b[2][2] = (s) * a[2][2]; \
734	}\
735
736
737	/! multiply matrix by scalar /
738	#define SCALE_MATRIX_4X4(b,s,a) \
739	{ \
740	b[0][0] = (s) * a[0][0]; \
741	b[0][1] = (s) * a[0][1]; \
742	b[0][2] = (s) * a[0][2]; \
743	b[0][3] = (s) * a[0][3]; \
744	\
745	b[1][0] = (s) * a[1][0]; \
746	b[1][1] = (s) * a[1][1]; \
747	b[1][2] = (s) * a[1][2]; \
748	b[1][3] = (s) * a[1][3]; \
749	\
750	b[2][0] = (s) * a[2][0]; \
751	b[2][1] = (s) * a[2][1]; \
752	b[2][2] = (s) * a[2][2]; \
753	b[2][3] = (s) * a[2][3]; \
754	\
755	b[3][0] = s * a[3][0]; \
756	b[3][1] = s * a[3][1]; \
757	b[3][2] = s * a[3][2]; \
758	b[3][3] = s * a[3][3]; \
759	}\
760
761
762	/! multiply matrix by scalar /
763	#define SCALE_VEC_MATRIX_2X2(b,svec,a) \
764	{ \
765	b[0][0] = svec[0] * a[0][0]; \
766	b[1][0] = svec[0] * a[1][0]; \
767	\
768	b[0][1] = svec[1] * a[0][1]; \
769	b[1][1] = svec[1] * a[1][1]; \
770	}\
771
772
773	/! multiply matrix by scalar. Each columns is scaled by each scalar vector component /
774	#define SCALE_VEC_MATRIX_3X3(b,svec,a) \
775	{ \
776	b[0][0] = svec[0] * a[0][0]; \
777	b[1][0] = svec[0] * a[1][0]; \
778	b[2][0] = svec[0] * a[2][0]; \
779	\
780	b[0][1] = svec[1] * a[0][1]; \
781	b[1][1] = svec[1] * a[1][1]; \
782	b[2][1] = svec[1] * a[2][1]; \
783	\
784	b[0][2] = svec[2] * a[0][2]; \
785	b[1][2] = svec[2] * a[1][2]; \
786	b[2][2] = svec[2] * a[2][2]; \
787	}\
788
789
790	/! multiply matrix by scalar /
791	#define SCALE_VEC_MATRIX_4X4(b,svec,a) \
792	{ \
793	b[0][0] = svec[0] * a[0][0]; \
794	b[1][0] = svec[0] * a[1][0]; \
795	b[2][0] = svec[0] * a[2][0]; \
796	b[3][0] = svec[0] * a[3][0]; \
797	\
798	b[0][1] = svec[1] * a[0][1]; \
799	b[1][1] = svec[1] * a[1][1]; \
800	b[2][1] = svec[1] * a[2][1]; \
801	b[3][1] = svec[1] * a[3][1]; \
802	\
803	b[0][2] = svec[2] * a[0][2]; \
804	b[1][2] = svec[2] * a[1][2]; \
805	b[2][2] = svec[2] * a[2][2]; \
806	b[3][2] = svec[2] * a[3][2]; \
807	\
808	b[0][3] = svec[3] * a[0][3]; \
809	b[1][3] = svec[3] * a[1][3]; \
810	b[2][3] = svec[3] * a[2][3]; \
811	b[3][3] = svec[3] * a[3][3]; \
812	}\
813
814
815	/! multiply matrix by scalar /
816	#define ACCUM_SCALE_MATRIX_2X2(b,s,a) \
817	{ \
818	b[0][0] += (s) * a[0][0]; \
819	b[0][1] += (s) * a[0][1]; \
820	\
821	b[1][0] += (s) * a[1][0]; \
822	b[1][1] += (s) * a[1][1]; \
823	}\
824
825
826	/! multiply matrix by scalar /
827	#define ACCUM_SCALE_MATRIX_3X3(b,s,a) \
828	{ \
829	b[0][0] += (s) * a[0][0]; \
830	b[0][1] += (s) * a[0][1]; \
831	b[0][2] += (s) * a[0][2]; \
832	\
833	b[1][0] += (s) * a[1][0]; \
834	b[1][1] += (s) * a[1][1]; \
835	b[1][2] += (s) * a[1][2]; \
836	\
837	b[2][0] += (s) * a[2][0]; \
838	b[2][1] += (s) * a[2][1]; \
839	b[2][2] += (s) * a[2][2]; \
840	}\
841
842
843	/! multiply matrix by scalar /
844	#define ACCUM_SCALE_MATRIX_4X4(b,s,a) \
845	{ \
846	b[0][0] += (s) * a[0][0]; \
847	b[0][1] += (s) * a[0][1]; \
848	b[0][2] += (s) * a[0][2]; \
849	b[0][3] += (s) * a[0][3]; \
850	\
851	b[1][0] += (s) * a[1][0]; \
852	b[1][1] += (s) * a[1][1]; \
853	b[1][2] += (s) * a[1][2]; \
854	b[1][3] += (s) * a[1][3]; \
855	\
856	b[2][0] += (s) * a[2][0]; \
857	b[2][1] += (s) * a[2][1]; \
858	b[2][2] += (s) * a[2][2]; \
859	b[2][3] += (s) * a[2][3]; \
860	\
861	b[3][0] += (s) * a[3][0]; \
862	b[3][1] += (s) * a[3][1]; \
863	b[3][2] += (s) * a[3][2]; \
864	b[3][3] += (s) * a[3][3]; \
865	}\
866
867	/! matrix product /
868	/! c[x][y] = a[x][0]b[0][y]+a[x][1]b[1][y]+a[x][2]b[2][y]+a[x][3]b[3][y];/
869	#define MATRIX_PRODUCT_2X2(c,a,b) \
870	{ \
871	c[0][0] = a[0][0]b[0][0]+a[0][1]b[1][0]; \
872	c[0][1] = a[0][0]b[0][1]+a[0][1]b[1][1]; \
873	\
874	c[1][0] = a[1][0]b[0][0]+a[1][1]b[1][0]; \
875	c[1][1] = a[1][0]b[0][1]+a[1][1]b[1][1]; \
876	\
877	}\
878
879	/! matrix product /
880	/! c[x][y] = a[x][0]b[0][y]+a[x][1]b[1][y]+a[x][2]b[2][y]+a[x][3]b[3][y];/
881	#define MATRIX_PRODUCT_3X3(c,a,b) \
882	{ \
883	c[0][0] = a[0][0]b[0][0]+a[0][1]b[1][0]+a[0][2]*b[2][0]; \
884	c[0][1] = a[0][0]b[0][1]+a[0][1]b[1][1]+a[0][2]*b[2][1]; \
885	c[0][2] = a[0][0]b[0][2]+a[0][1]b[1][2]+a[0][2]*b[2][2]; \
886	\
887	c[1][0] = a[1][0]b[0][0]+a[1][1]b[1][0]+a[1][2]*b[2][0]; \
888	c[1][1] = a[1][0]b[0][1]+a[1][1]b[1][1]+a[1][2]*b[2][1]; \
889	c[1][2] = a[1][0]b[0][2]+a[1][1]b[1][2]+a[1][2]*b[2][2]; \
890	\
891	c[2][0] = a[2][0]b[0][0]+a[2][1]b[1][0]+a[2][2]*b[2][0]; \
892	c[2][1] = a[2][0]b[0][1]+a[2][1]b[1][1]+a[2][2]*b[2][1]; \
893	c[2][2] = a[2][0]b[0][2]+a[2][1]b[1][2]+a[2][2]*b[2][2]; \
894	}\
895
896
897	/! matrix product /
898	/! c[x][y] = a[x][0]b[0][y]+a[x][1]b[1][y]+a[x][2]b[2][y]+a[x][3]b[3][y];/
899	#define MATRIX_PRODUCT_4X4(c,a,b) \
900	{ \
901	c[0][0] = a[0][0]b[0][0]+a[0][1]b[1][0]+a[0][2]b[2][0]+a[0][3]b[3][0];\
902	c[0][1] = a[0][0]b[0][1]+a[0][1]b[1][1]+a[0][2]b[2][1]+a[0][3]b[3][1];\
903	c[0][2] = a[0][0]b[0][2]+a[0][1]b[1][2]+a[0][2]b[2][2]+a[0][3]b[3][2];\
904	c[0][3] = a[0][0]b[0][3]+a[0][1]b[1][3]+a[0][2]b[2][3]+a[0][3]b[3][3];\
905	\
906	c[1][0] = a[1][0]b[0][0]+a[1][1]b[1][0]+a[1][2]b[2][0]+a[1][3]b[3][0];\
907	c[1][1] = a[1][0]b[0][1]+a[1][1]b[1][1]+a[1][2]b[2][1]+a[1][3]b[3][1];\
908	c[1][2] = a[1][0]b[0][2]+a[1][1]b[1][2]+a[1][2]b[2][2]+a[1][3]b[3][2];\
909	c[1][3] = a[1][0]b[0][3]+a[1][1]b[1][3]+a[1][2]b[2][3]+a[1][3]b[3][3];\
910	\
911	c[2][0] = a[2][0]b[0][0]+a[2][1]b[1][0]+a[2][2]b[2][0]+a[2][3]b[3][0];\
912	c[2][1] = a[2][0]b[0][1]+a[2][1]b[1][1]+a[2][2]b[2][1]+a[2][3]b[3][1];\
913	c[2][2] = a[2][0]b[0][2]+a[2][1]b[1][2]+a[2][2]b[2][2]+a[2][3]b[3][2];\
914	c[2][3] = a[2][0]b[0][3]+a[2][1]b[1][3]+a[2][2]b[2][3]+a[2][3]b[3][3];\
915	\
916	c[3][0] = a[3][0]b[0][0]+a[3][1]b[1][0]+a[3][2]b[2][0]+a[3][3]b[3][0];\
917	c[3][1] = a[3][0]b[0][1]+a[3][1]b[1][1]+a[3][2]b[2][1]+a[3][3]b[3][1];\
918	c[3][2] = a[3][0]b[0][2]+a[3][1]b[1][2]+a[3][2]b[2][2]+a[3][3]b[3][2];\
919	c[3][3] = a[3][0]b[0][3]+a[3][1]b[1][3]+a[3][2]b[2][3]+a[3][3]b[3][3];\
920	}\
921
922
923	/! matrix times vector /
924	#define MAT_DOT_VEC_2X2(p,m,v) \
925	{ \
926	p[0] = m[0][0]v[0] + m[0][1]v[1]; \
927	p[1] = m[1][0]v[0] + m[1][1]v[1]; \
928	}\
929
930
931	/! matrix times vector /
932	#define MAT_DOT_VEC_3X3(p,m,v) \
933	{ \
934	p[0] = m[0][0]v[0] + m[0][1]v[1] + m[0][2]*v[2]; \
935	p[1] = m[1][0]v[0] + m[1][1]v[1] + m[1][2]*v[2]; \
936	p[2] = m[2][0]v[0] + m[2][1]v[1] + m[2][2]*v[2]; \
937	}\
938
939
940	/*! matrix times vector
941	v is a vec4f
942	*/
943	#define MAT_DOT_VEC_4X4(p,m,v) \
944	{ \
945	p[0] = m[0][0]v[0] + m[0][1]v[1] + m[0][2]v[2] + m[0][3]v[3]; \
946	p[1] = m[1][0]v[0] + m[1][1]v[1] + m[1][2]v[2] + m[1][3]v[3]; \
947	p[2] = m[2][0]v[0] + m[2][1]v[1] + m[2][2]v[2] + m[2][3]v[3]; \
948	p[3] = m[3][0]v[0] + m[3][1]v[1] + m[3][2]v[2] + m[3][3]v[3]; \
949	}\
950
951	/*! matrix times vector
952	v is a vec3f
953	and m is a mat4f<br>
954	Last column is added as the position
955	*/
956	#define MAT_DOT_VEC_3X4(p,m,v) \
957	{ \
958	p[0] = m[0][0]v[0] + m[0][1]v[1] + m[0][2]*v[2] + m[0][3]; \
959	p[1] = m[1][0]v[0] + m[1][1]v[1] + m[1][2]*v[2] + m[1][3]; \
960	p[2] = m[2][0]v[0] + m[2][1]v[1] + m[2][2]*v[2] + m[2][3]; \
961	}\
962
963
964	/! vector transpose times matrix /
965	/! p[j] = v[0]m[0][j] + v[1]m[1][j] + v[2]m[2][j]; */
966	#define VEC_DOT_MAT_3X3(p,v,m) \
967	{ \
968	p[0] = v[0]m[0][0] + v[1]m[1][0] + v[2]*m[2][0]; \
969	p[1] = v[0]m[0][1] + v[1]m[1][1] + v[2]*m[2][1]; \
970	p[2] = v[0]m[0][2] + v[1]m[1][2] + v[2]*m[2][2]; \
971	}\
972
973
974	/! affine matrix times vector /
975	/** The matrix is assumed to be an affine matrix, with last two
976	* entries representing a translation */
977	#define MAT_DOT_VEC_2X3(p,m,v) \
978	{ \
979	p[0] = m[0][0]v[0] + m[0][1]v[1] + m[0][2]; \
980	p[1] = m[1][0]v[0] + m[1][1]v[1] + m[1][2]; \
981	}\
982
983	//! Transform a plane
984	#define MAT_TRANSFORM_PLANE_4X4(pout,m,plane)\
985	{ \
986	pout[0] = m[0][0]plane[0] + m[0][1]plane[1] + m[0][2]*plane[2];\
987	pout[1] = m[1][0]plane[0] + m[1][1]plane[1] + m[1][2]*plane[2];\
988	pout[2] = m[2][0]plane[0] + m[2][1]plane[1] + m[2][2]*plane[2];\
989	pout[3] = m[0][3]pout[0] + m[1][3]pout[1] + m[2][3]*pout[2] + plane[3];\
990	}\
991
992
993
994	/** inverse transpose of matrix times vector
995	*
996	* This macro computes inverse transpose of matrix m,
997	* and multiplies vector v into it, to yeild vector p
998	*
999	* DANGER !!! Do Not use this on normal vectors!!!
1000	* It will leave normals the wrong length !!!
1001	* See macro below for use on normals.
1002	*/
1003	#define INV_TRANSP_MAT_DOT_VEC_2X2(p,m,v) \
1004	{ \
1005	GREAL det; \
1006	\
1007	det = m[0][0]m[1][1] - m[0][1]m[1][0]; \
1008	p[0] = m[1][1]v[0] - m[1][0]v[1]; \
1009	p[1] = - m[0][1]v[0] + m[0][0]v[1]; \
1010	\
1011	/* if matrix not singular, and not orthonormal, then renormalize */ \
1012	if ((det!=1.0f) && (det != 0.0f)) { \
1013	det = 1.0f / det; \
1014	p[0] *= det; \
1015	p[1] *= det; \
1016	} \
1017	}\
1018
1019
1020	/** transform normal vector by inverse transpose of matrix
1021	* and then renormalize the vector
1022	*
1023	* This macro computes inverse transpose of matrix m,
1024	* and multiplies vector v into it, to yeild vector p
1025	* Vector p is then normalized.
1026	*/
1027	#define NORM_XFORM_2X2(p,m,v) \
1028	{ \
1029	GREAL len; \
1030	\
1031	/* do nothing if off-diagonals are zero and diagonals are \
1032	* equal */ \
1033	if ((m[0][1] != 0.0) \|\| (m[1][0] != 0.0) \|\| (m[0][0] != m[1][1])) { \
1034	p[0] = m[1][1]v[0] - m[1][0]v[1]; \
1035	p[1] = - m[0][1]v[0] + m[0][0]v[1]; \
1036	\
1037	len = p[0]p[0] + p[1]p[1]; \
1038	GIM_INV_SQRT(len,len); \
1039	p[0] *= len; \
1040	p[1] *= len; \
1041	} else { \
1042	VEC_COPY_2 (p, v); \
1043	} \
1044	}\
1045
1046
1047	/** outer product of vector times vector transpose
1048	*
1049	* The outer product of vector v and vector transpose t yeilds
1050	* dyadic matrix m.
1051	*/
1052	#define OUTER_PRODUCT_2X2(m,v,t) \
1053	{ \
1054	m[0][0] = v[0] * t[0]; \
1055	m[0][1] = v[0] * t[1]; \
1056	\
1057	m[1][0] = v[1] * t[0]; \
1058	m[1][1] = v[1] * t[1]; \
1059	}\
1060
1061
1062	/** outer product of vector times vector transpose
1063	*
1064	* The outer product of vector v and vector transpose t yeilds
1065	* dyadic matrix m.
1066	*/
1067	#define OUTER_PRODUCT_3X3(m,v,t) \
1068	{ \
1069	m[0][0] = v[0] * t[0]; \
1070	m[0][1] = v[0] * t[1]; \
1071	m[0][2] = v[0] * t[2]; \
1072	\
1073	m[1][0] = v[1] * t[0]; \
1074	m[1][1] = v[1] * t[1]; \
1075	m[1][2] = v[1] * t[2]; \
1076	\
1077	m[2][0] = v[2] * t[0]; \
1078	m[2][1] = v[2] * t[1]; \
1079	m[2][2] = v[2] * t[2]; \
1080	}\
1081
1082
1083	/** outer product of vector times vector transpose
1084	*
1085	* The outer product of vector v and vector transpose t yeilds
1086	* dyadic matrix m.
1087	*/
1088	#define OUTER_PRODUCT_4X4(m,v,t) \
1089	{ \
1090	m[0][0] = v[0] * t[0]; \
1091	m[0][1] = v[0] * t[1]; \
1092	m[0][2] = v[0] * t[2]; \
1093	m[0][3] = v[0] * t[3]; \
1094	\
1095	m[1][0] = v[1] * t[0]; \
1096	m[1][1] = v[1] * t[1]; \
1097	m[1][2] = v[1] * t[2]; \
1098	m[1][3] = v[1] * t[3]; \
1099	\
1100	m[2][0] = v[2] * t[0]; \
1101	m[2][1] = v[2] * t[1]; \
1102	m[2][2] = v[2] * t[2]; \
1103	m[2][3] = v[2] * t[3]; \
1104	\
1105	m[3][0] = v[3] * t[0]; \
1106	m[3][1] = v[3] * t[1]; \
1107	m[3][2] = v[3] * t[2]; \
1108	m[3][3] = v[3] * t[3]; \
1109	}\
1110
1111
1112	/** outer product of vector times vector transpose
1113	*
1114	* The outer product of vector v and vector transpose t yeilds
1115	* dyadic matrix m.
1116	*/
1117	#define ACCUM_OUTER_PRODUCT_2X2(m,v,t) \
1118	{ \
1119	m[0][0] += v[0] * t[0]; \
1120	m[0][1] += v[0] * t[1]; \
1121	\
1122	m[1][0] += v[1] * t[0]; \
1123	m[1][1] += v[1] * t[1]; \
1124	}\
1125
1126
1127	/** outer product of vector times vector transpose
1128	*
1129	* The outer product of vector v and vector transpose t yeilds
1130	* dyadic matrix m.
1131	*/
1132	#define ACCUM_OUTER_PRODUCT_3X3(m,v,t) \
1133	{ \
1134	m[0][0] += v[0] * t[0]; \
1135	m[0][1] += v[0] * t[1]; \
1136	m[0][2] += v[0] * t[2]; \
1137	\
1138	m[1][0] += v[1] * t[0]; \
1139	m[1][1] += v[1] * t[1]; \
1140	m[1][2] += v[1] * t[2]; \
1141	\
1142	m[2][0] += v[2] * t[0]; \
1143	m[2][1] += v[2] * t[1]; \
1144	m[2][2] += v[2] * t[2]; \
1145	}\
1146
1147
1148	/** outer product of vector times vector transpose
1149	*
1150	* The outer product of vector v and vector transpose t yeilds
1151	* dyadic matrix m.
1152	*/
1153	#define ACCUM_OUTER_PRODUCT_4X4(m,v,t) \
1154	{ \
1155	m[0][0] += v[0] * t[0]; \
1156	m[0][1] += v[0] * t[1]; \
1157	m[0][2] += v[0] * t[2]; \
1158	m[0][3] += v[0] * t[3]; \
1159	\
1160	m[1][0] += v[1] * t[0]; \
1161	m[1][1] += v[1] * t[1]; \
1162	m[1][2] += v[1] * t[2]; \
1163	m[1][3] += v[1] * t[3]; \
1164	\
1165	m[2][0] += v[2] * t[0]; \
1166	m[2][1] += v[2] * t[1]; \
1167	m[2][2] += v[2] * t[2]; \
1168	m[2][3] += v[2] * t[3]; \
1169	\
1170	m[3][0] += v[3] * t[0]; \
1171	m[3][1] += v[3] * t[1]; \
1172	m[3][2] += v[3] * t[2]; \
1173	m[3][3] += v[3] * t[3]; \
1174	}\
1175
1176
1177	/** determinant of matrix
1178	*
1179	* Computes determinant of matrix m, returning d
1180	*/
1181	#define DETERMINANT_2X2(d,m) \
1182	{ \
1183	d = m[0][0] * m[1][1] - m[0][1] * m[1][0]; \
1184	}\
1185
1186
1187	/** determinant of matrix
1188	*
1189	* Computes determinant of matrix m, returning d
1190	*/
1191	#define DETERMINANT_3X3(d,m) \
1192	{ \
1193	d = m[0][0] * (m[1][1]m[2][2] - m[1][2] m[2][1]); \
1194	d -= m[0][1] * (m[1][0]m[2][2] - m[1][2] m[2][0]); \
1195	d += m[0][2] * (m[1][0]m[2][1] - m[1][1] m[2][0]); \
1196	}\
1197
1198
1199	/** i,j,th cofactor of a 4x4 matrix
1200	*
1201	*/
1202	#define COFACTOR_4X4_IJ(fac,m,i,j) \
1203	{ \
1204	GUINT __ii[4], __jj[4], __k; \
1205	\
1206	for (__k=0; __k<i; __k++) __ii[__k] = __k; \
1207	for (__k=i; __k<3; __k++) __ii[__k] = __k+1; \
1208	for (__k=0; __k<j; __k++) __jj[__k] = __k; \
1209	for (__k=j; __k<3; __k++) __jj[__k] = __k+1; \
1210	\
1211	(fac) = m[__ii[0]][__jj[0]] * (m[__ii[1]][__jj[1]]*m[__ii[2]][__jj[2]] \
1212	- m[__ii[1]][__jj[2]]*m[__ii[2]][__jj[1]]); \
1213	(fac) -= m[__ii[0]][__jj[1]] * (m[__ii[1]][__jj[0]]*m[__ii[2]][__jj[2]] \
1214	- m[__ii[1]][__jj[2]]*m[__ii[2]][__jj[0]]);\
1215	(fac) += m[__ii[0]][__jj[2]] * (m[__ii[1]][__jj[0]]*m[__ii[2]][__jj[1]] \
1216	- m[__ii[1]][__jj[1]]*m[__ii[2]][__jj[0]]);\
1217	\
1218	__k = i+j; \
1219	if ( __k != (__k/2)*2) { \
1220	(fac) = -(fac); \
1221	} \
1222	}\
1223
1224
1225	/** determinant of matrix
1226	*
1227	* Computes determinant of matrix m, returning d
1228	*/
1229	#define DETERMINANT_4X4(d,m) \
1230	{ \
1231	GREAL cofac; \
1232	COFACTOR_4X4_IJ (cofac, m, 0, 0); \
1233	d = m[0][0] * cofac; \
1234	COFACTOR_4X4_IJ (cofac, m, 0, 1); \
1235	d += m[0][1] * cofac; \
1236	COFACTOR_4X4_IJ (cofac, m, 0, 2); \
1237	d += m[0][2] * cofac; \
1238	COFACTOR_4X4_IJ (cofac, m, 0, 3); \
1239	d += m[0][3] * cofac; \
1240	}\
1241
1242
1243	/** cofactor of matrix
1244	*
1245	* Computes cofactor of matrix m, returning a
1246	*/
1247	#define COFACTOR_2X2(a,m) \
1248	{ \
1249	a[0][0] = (m)[1][1]; \
1250	a[0][1] = - (m)[1][0]; \
1251	a[1][0] = - (m)[0][1]; \
1252	a[1][1] = (m)[0][0]; \
1253	}\
1254
1255
1256	/** cofactor of matrix
1257	*
1258	* Computes cofactor of matrix m, returning a
1259	*/
1260	#define COFACTOR_3X3(a,m) \
1261	{ \
1262	a[0][0] = m[1][1]m[2][2] - m[1][2]m[2][1]; \
1263	a[0][1] = - (m[1][0]m[2][2] - m[2][0]m[1][2]); \
1264	a[0][2] = m[1][0]m[2][1] - m[1][1]m[2][0]; \
1265	a[1][0] = - (m[0][1]m[2][2] - m[0][2]m[2][1]); \
1266	a[1][1] = m[0][0]m[2][2] - m[0][2]m[2][0]; \
1267	a[1][2] = - (m[0][0]m[2][1] - m[0][1]m[2][0]); \
1268	a[2][0] = m[0][1]m[1][2] - m[0][2]m[1][1]; \
1269	a[2][1] = - (m[0][0]m[1][2] - m[0][2]m[1][0]); \
1270	a[2][2] = m[0][0]m[1][1] - m[0][1]m[1][0]); \
1271	}\
1272
1273
1274	/** cofactor of matrix
1275	*
1276	* Computes cofactor of matrix m, returning a
1277	*/
1278	#define COFACTOR_4X4(a,m) \
1279	{ \
1280	int i,j; \
1281	\
1282	for (i=0; i<4; i++) { \
1283	for (j=0; j<4; j++) { \
1284	COFACTOR_4X4_IJ (a[i][j], m, i, j); \
1285	} \
1286	} \
1287	}\
1288
1289
1290	/** adjoint of matrix
1291	*
1292	* Computes adjoint of matrix m, returning a
1293	* (Note that adjoint is just the transpose of the cofactor matrix)
1294	*/
1295	#define ADJOINT_2X2(a,m) \
1296	{ \
1297	a[0][0] = (m)[1][1]; \
1298	a[1][0] = - (m)[1][0]; \
1299	a[0][1] = - (m)[0][1]; \
1300	a[1][1] = (m)[0][0]; \
1301	}\
1302
1303
1304	/** adjoint of matrix
1305	*
1306	* Computes adjoint of matrix m, returning a
1307	* (Note that adjoint is just the transpose of the cofactor matrix)
1308	*/
1309	#define ADJOINT_3X3(a,m) \
1310	{ \
1311	a[0][0] = m[1][1]m[2][2] - m[1][2]m[2][1]; \
1312	a[1][0] = - (m[1][0]m[2][2] - m[2][0]m[1][2]); \
1313	a[2][0] = m[1][0]m[2][1] - m[1][1]m[2][0]; \
1314	a[0][1] = - (m[0][1]m[2][2] - m[0][2]m[2][1]); \
1315	a[1][1] = m[0][0]m[2][2] - m[0][2]m[2][0]; \
1316	a[2][1] = - (m[0][0]m[2][1] - m[0][1]m[2][0]); \
1317	a[0][2] = m[0][1]m[1][2] - m[0][2]m[1][1]; \
1318	a[1][2] = - (m[0][0]m[1][2] - m[0][2]m[1][0]); \
1319	a[2][2] = m[0][0]m[1][1] - m[0][1]m[1][0]); \
1320	}\
1321
1322
1323	/** adjoint of matrix
1324	*
1325	* Computes adjoint of matrix m, returning a
1326	* (Note that adjoint is just the transpose of the cofactor matrix)
1327	*/
1328	#define ADJOINT_4X4(a,m) \
1329	{ \
1330	char _i_,_j_; \
1331	\
1332	for (_i_=0; _i_<4; _i_++) { \
1333	for (_j_=0; _j_<4; _j_++) { \
1334	COFACTOR_4X4_IJ (a[_j_][_i_], m, _i_, _j_); \
1335	} \
1336	} \
1337	}\
1338
1339
1340	/** compute adjoint of matrix and scale
1341	*
1342	* Computes adjoint of matrix m, scales it by s, returning a
1343	*/
1344	#define SCALE_ADJOINT_2X2(a,s,m) \
1345	{ \
1346	a[0][0] = (s) * m[1][1]; \
1347	a[1][0] = - (s) * m[1][0]; \
1348	a[0][1] = - (s) * m[0][1]; \
1349	a[1][1] = (s) * m[0][0]; \
1350	}\
1351
1352
1353	/** compute adjoint of matrix and scale
1354	*
1355	* Computes adjoint of matrix m, scales it by s, returning a
1356	*/
1357	#define SCALE_ADJOINT_3X3(a,s,m) \
1358	{ \
1359	a[0][0] = (s) * (m[1][1] * m[2][2] - m[1][2] * m[2][1]); \
1360	a[1][0] = (s) * (m[1][2] * m[2][0] - m[1][0] * m[2][2]); \
1361	a[2][0] = (s) * (m[1][0] * m[2][1] - m[1][1] * m[2][0]); \
1362	\
1363	a[0][1] = (s) * (m[0][2] * m[2][1] - m[0][1] * m[2][2]); \
1364	a[1][1] = (s) * (m[0][0] * m[2][2] - m[0][2] * m[2][0]); \
1365	a[2][1] = (s) * (m[0][1] * m[2][0] - m[0][0] * m[2][1]); \
1366	\
1367	a[0][2] = (s) * (m[0][1] * m[1][2] - m[0][2] * m[1][1]); \
1368	a[1][2] = (s) * (m[0][2] * m[1][0] - m[0][0] * m[1][2]); \
1369	a[2][2] = (s) * (m[0][0] * m[1][1] - m[0][1] * m[1][0]); \
1370	}\
1371
1372
1373	/** compute adjoint of matrix and scale
1374	*
1375	* Computes adjoint of matrix m, scales it by s, returning a
1376	*/
1377	#define SCALE_ADJOINT_4X4(a,s,m) \
1378	{ \
1379	char _i_,_j_; \
1380	for (_i_=0; _i_<4; _i_++) { \
1381	for (_j_=0; _j_<4; _j_++) { \
1382	COFACTOR_4X4_IJ (a[_j_][_i_], m, _i_, _j_); \
1383	a[_j_][_i_] *= s; \
1384	} \
1385	} \
1386	}\
1387
1388	/** inverse of matrix
1389	*
1390	* Compute inverse of matrix a, returning determinant m and
1391	* inverse b
1392	*/
1393	#define INVERT_2X2(b,det,a) \
1394	{ \
1395	GREAL _tmp_; \
1396	DETERMINANT_2X2 (det, a); \
1397	_tmp_ = 1.0 / (det); \
1398	SCALE_ADJOINT_2X2 (b, _tmp_, a); \
1399	}\
1400
1401
1402	/** inverse of matrix
1403	*
1404	* Compute inverse of matrix a, returning determinant m and
1405	* inverse b
1406	*/
1407	#define INVERT_3X3(b,det,a) \
1408	{ \
1409	GREAL _tmp_; \
1410	DETERMINANT_3X3 (det, a); \
1411	_tmp_ = 1.0 / (det); \
1412	SCALE_ADJOINT_3X3 (b, _tmp_, a); \
1413	}\
1414
1415
1416	/** inverse of matrix
1417	*
1418	* Compute inverse of matrix a, returning determinant m and
1419	* inverse b
1420	*/
1421	#define INVERT_4X4(b,det,a) \
1422	{ \
1423	GREAL _tmp_; \
1424	DETERMINANT_4X4 (det, a); \
1425	_tmp_ = 1.0 / (det); \
1426	SCALE_ADJOINT_4X4 (b, _tmp_, a); \
1427	}\
1428
1429	//! Get the triple(3) row of a transform matrix
1430	#define MAT_GET_ROW(mat,vec3,rowindex)\
1431	{\
1432	vec3[0] = mat[rowindex][0];\
1433	vec3[1] = mat[rowindex][1];\
1434	vec3[2] = mat[rowindex][2]; \
1435	}\
1436
1437	//! Get the tuple(2) row of a transform matrix
1438	#define MAT_GET_ROW2(mat,vec2,rowindex)\
1439	{\
1440	vec2[0] = mat[rowindex][0];\
1441	vec2[1] = mat[rowindex][1];\
1442	}\
1443
1444
1445	//! Get the quad (4) row of a transform matrix
1446	#define MAT_GET_ROW4(mat,vec4,rowindex)\
1447	{\
1448	vec4[0] = mat[rowindex][0];\
1449	vec4[1] = mat[rowindex][1];\
1450	vec4[2] = mat[rowindex][2];\
1451	vec4[3] = mat[rowindex][3];\
1452	}\
1453
1454	//! Get the triple(3) col of a transform matrix
1455	#define MAT_GET_COL(mat,vec3,colindex)\
1456	{\
1457	vec3[0] = mat[0][colindex];\
1458	vec3[1] = mat[1][colindex];\
1459	vec3[2] = mat[2][colindex]; \
1460	}\
1461
1462	//! Get the tuple(2) col of a transform matrix
1463	#define MAT_GET_COL2(mat,vec2,colindex)\
1464	{\
1465	vec2[0] = mat[0][colindex];\
1466	vec2[1] = mat[1][colindex];\
1467	}\
1468
1469
1470	//! Get the quad (4) col of a transform matrix
1471	#define MAT_GET_COL4(mat,vec4,colindex)\
1472	{\
1473	vec4[0] = mat[0][colindex];\
1474	vec4[1] = mat[1][colindex];\
1475	vec4[2] = mat[2][colindex];\
1476	vec4[3] = mat[3][colindex];\
1477	}\
1478
1479	//! Get the triple(3) col of a transform matrix
1480	#define MAT_GET_X(mat,vec3)\
1481	{\
1482	MAT_GET_COL(mat,vec3,0);\
1483	}\
1484
1485	//! Get the triple(3) col of a transform matrix
1486	#define MAT_GET_Y(mat,vec3)\
1487	{\
1488	MAT_GET_COL(mat,vec3,1);\
1489	}\
1490
1491	//! Get the triple(3) col of a transform matrix
1492	#define MAT_GET_Z(mat,vec3)\
1493	{\
1494	MAT_GET_COL(mat,vec3,2);\
1495	}\
1496
1497
1498	//! Get the triple(3) col of a transform matrix
1499	#define MAT_SET_X(mat,vec3)\
1500	{\
1501	mat[0][0] = vec3[0];\
1502	mat[1][0] = vec3[1];\
1503	mat[2][0] = vec3[2];\
1504	}\
1505
1506	//! Get the triple(3) col of a transform matrix
1507	#define MAT_SET_Y(mat,vec3)\
1508	{\
1509	mat[0][1] = vec3[0];\
1510	mat[1][1] = vec3[1];\
1511	mat[2][1] = vec3[2];\
1512	}\
1513
1514	//! Get the triple(3) col of a transform matrix
1515	#define MAT_SET_Z(mat,vec3)\
1516	{\
1517	mat[0][2] = vec3[0];\
1518	mat[1][2] = vec3[1];\
1519	mat[2][2] = vec3[2];\
1520	}\
1521
1522
1523	//! Get the triple(3) col of a transform matrix
1524	#define MAT_GET_TRANSLATION(mat,vec3)\
1525	{\
1526	vec3[0] = mat[0][3];\
1527	vec3[1] = mat[1][3];\
1528	vec3[2] = mat[2][3]; \
1529	}\
1530
1531	//! Set the triple(3) col of a transform matrix
1532	#define MAT_SET_TRANSLATION(mat,vec3)\
1533	{\
1534	mat[0][3] = vec3[0];\
1535	mat[1][3] = vec3[1];\
1536	mat[2][3] = vec3[2]; \
1537	}\
1538
1539
1540
1541	//! Returns the dot product between a vec3f and the row of a matrix
1542	#define MAT_DOT_ROW(mat,vec3,rowindex) (vec3[0]mat[rowindex][0] + vec3[1]mat[rowindex][1] + vec3[2]*mat[rowindex][2])
1543
1544	//! Returns the dot product between a vec2f and the row of a matrix
1545	#define MAT_DOT_ROW2(mat,vec2,rowindex) (vec2[0]mat[rowindex][0] + vec2[1]mat[rowindex][1])
1546
1547	//! Returns the dot product between a vec4f and the row of a matrix
1548	#define MAT_DOT_ROW4(mat,vec4,rowindex) (vec4[0]mat[rowindex][0] + vec4[1]mat[rowindex][1] + vec4[2]mat[rowindex][2] + vec4[3]mat[rowindex][3])
1549
1550
1551	//! Returns the dot product between a vec3f and the col of a matrix
1552	#define MAT_DOT_COL(mat,vec3,colindex) (vec3[0]mat[0][colindex] + vec3[1]mat[1][colindex] + vec3[2]*mat[2][colindex])
1553
1554	//! Returns the dot product between a vec2f and the col of a matrix
1555	#define MAT_DOT_COL2(mat,vec2,colindex) (vec2[0]mat[0][colindex] + vec2[1]mat[1][colindex])
1556
1557	//! Returns the dot product between a vec4f and the col of a matrix
1558	#define MAT_DOT_COL4(mat,vec4,colindex) (vec4[0]mat[0][colindex] + vec4[1]mat[1][colindex] + vec4[2]mat[2][colindex] + vec4[3]mat[3][colindex])
1559
1560	/*!Transpose matrix times vector
1561	v is a vec3f
1562	and m is a mat4f<br>
1563	*/
1564	#define INV_MAT_DOT_VEC_3X3(p,m,v) \
1565	{ \
1566	p[0] = MAT_DOT_COL(m,v,0); \
1567	p[1] = MAT_DOT_COL(m,v,1); \
1568	p[2] = MAT_DOT_COL(m,v,2); \
1569	}\
1570
1571
1572
1573	#endif // GIM_VECTOR_H_INCLUDED

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