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MATRIX4X4.cpp @ 930

Revision 930, 24.4 KB checked in by igarcia, 18 years ago (diff)

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1	//////////////////////////////////////////////////////////////////////////////////////////
2	// MATRIX4X4.cpp
3	// function definitions for 4x4 matrix class
4	// You may use this code however you wish, but if you do, please credit me and
5	// provide a link to my website in a readme file or similar
6	// Downloaded from: www.paulsprojects.net
7	// Created: 20th July 2002
8	// Updated: 19th August 2002 - Corrected 2nd SetPerspective for n!=1.0f
9	// 26th September 2002 - Added nudge to prevent artifacts with infinite far plane
10	// - Improved speed
11	// 7th November 2002 - Added Affine Inverse functions
12	// - Changed constructors
13	// - Added special cases for row3 = (0, 0, 0, 1)
14	// 17th December 2002 - Converted from radians to degrees for consistency
15	// with OpenGL. Should have been done a long time ago...
16	//////////////////////////////////////////////////////////////////////////////////////////
17	#include <memory.h>
18	#include "Maths.h"
19
20	MATRIX4X4::MATRIX4X4(float e0, float e1, float e2, float e3,
21	float e4, float e5, float e6, float e7,
22	float e8, float e9, float e10, float e11,
23	float e12, float e13, float e14, float e15)
24	{
25	entries[0]=e0;
26	entries[1]=e1;
27	entries[2]=e2;
28	entries[3]=e3;
29	entries[4]=e4;
30	entries[5]=e5;
31	entries[6]=e6;
32	entries[7]=e7;
33	entries[8]=e8;
34	entries[9]=e9;
35	entries[10]=e10;
36	entries[11]=e11;
37	entries[12]=e12;
38	entries[13]=e13;
39	entries[14]=e14;
40	entries[15]=e15;
41	}
42
43	MATRIX4X4::MATRIX4X4(const MATRIX4X4 & rhs)
44	{
45	memcpy(entries, rhs.entries, 16*sizeof(float));
46	}
47
48	MATRIX4X4::MATRIX4X4(const float * rhs)
49	{
50	memcpy(entries, rhs, 16*sizeof(float));
51	}
52
53	void MATRIX4X4::SetEntry(int position, float value)
54	{
55	if(position>=0 && position<=15)
56	entries[position]=value;
57	}
58
59	float MATRIX4X4::GetEntry(int position) const
60	{
61	if(position>=0 && position<=15)
62	return entries[position];
63
64	return 0.0f;
65	}
66
67	VECTOR4D MATRIX4X4::GetRow(int position) const
68	{
69	if(position==0)
70	return VECTOR4D(entries[0], entries[4], entries[8], entries[12]);
71
72	if(position==1)
73	return VECTOR4D(entries[1], entries[5], entries[9], entries[13]);
74
75	if(position==2)
76	return VECTOR4D(entries[2], entries[6], entries[10], entries[14]);
77
78	if(position==3)
79	return VECTOR4D(entries[3], entries[7], entries[11], entries[15]);
80
81	return VECTOR4D(0.0f, 0.0f, 0.0f, 0.0f);
82	}
83
84	VECTOR4D MATRIX4X4::GetColumn(int position) const
85	{
86	if(position==0)
87	return VECTOR4D(entries[0], entries[1], entries[2], entries[3]);
88
89	if(position==1)
90	return VECTOR4D(entries[4], entries[5], entries[6], entries[7]);
91
92	if(position==2)
93	return VECTOR4D(entries[8], entries[9], entries[10], entries[11]);
94
95	if(position==3)
96	return VECTOR4D(entries[12], entries[13], entries[14], entries[15]);
97
98	return VECTOR4D(0.0f, 0.0f, 0.0f, 0.0f);
99	}
100
101	void MATRIX4X4::LoadIdentity(void)
102	{
103	memset(entries, 0, 16*sizeof(float));
104	entries[0]=1.0f;
105	entries[5]=1.0f;
106	entries[10]=1.0f;
107	entries[15]=1.0f;
108	}
109
110	void MATRIX4X4::LoadZero(void)
111	{
112	memset(entries, 0, 16*sizeof(float));
113	}
114
115	MATRIX4X4 MATRIX4X4::operator+(const MATRIX4X4 & rhs) const //overloaded operators
116	{
117	return MATRIX4X4( entries[0]+rhs.entries[0],
118	entries[1]+rhs.entries[1],
119	entries[2]+rhs.entries[2],
120	entries[3]+rhs.entries[3],
121	entries[4]+rhs.entries[4],
122	entries[5]+rhs.entries[5],
123	entries[6]+rhs.entries[6],
124	entries[7]+rhs.entries[7],
125	entries[8]+rhs.entries[8],
126	entries[9]+rhs.entries[9],
127	entries[10]+rhs.entries[10],
128	entries[11]+rhs.entries[11],
129	entries[12]+rhs.entries[12],
130	entries[13]+rhs.entries[13],
131	entries[14]+rhs.entries[14],
132	entries[15]+rhs.entries[15]);
133	}
134
135	MATRIX4X4 MATRIX4X4::operator-(const MATRIX4X4 & rhs) const //overloaded operators
136	{
137	return MATRIX4X4( entries[0]-rhs.entries[0],
138	entries[1]-rhs.entries[1],
139	entries[2]-rhs.entries[2],
140	entries[3]-rhs.entries[3],
141	entries[4]-rhs.entries[4],
142	entries[5]-rhs.entries[5],
143	entries[6]-rhs.entries[6],
144	entries[7]-rhs.entries[7],
145	entries[8]-rhs.entries[8],
146	entries[9]-rhs.entries[9],
147	entries[10]-rhs.entries[10],
148	entries[11]-rhs.entries[11],
149	entries[12]-rhs.entries[12],
150	entries[13]-rhs.entries[13],
151	entries[14]-rhs.entries[14],
152	entries[15]-rhs.entries[15]);
153	}
154
155	MATRIX4X4 MATRIX4X4::operator*(const MATRIX4X4 & rhs) const
156	{
157	//Optimise for matrices in which bottom row is (0, 0, 0, 1) in both matrices
158	if( entries[3]==0.0f && entries[7]==0.0f && entries[11]==0.0f && entries[15]==1.0f &&
159	rhs.entries[3]==0.0f && rhs.entries[7]==0.0f &&
160	rhs.entries[11]==0.0f && rhs.entries[15]==1.0f)
161	{
162	return MATRIX4X4( entries[0]rhs.entries[0]+entries[4]rhs.entries[1]+entries[8]*rhs.entries[2],
163	entries[1]rhs.entries[0]+entries[5]rhs.entries[1]+entries[9]*rhs.entries[2],
164	entries[2]rhs.entries[0]+entries[6]rhs.entries[1]+entries[10]*rhs.entries[2],
165	0.0f,
166	entries[0]rhs.entries[4]+entries[4]rhs.entries[5]+entries[8]*rhs.entries[6],
167	entries[1]rhs.entries[4]+entries[5]rhs.entries[5]+entries[9]*rhs.entries[6],
168	entries[2]rhs.entries[4]+entries[6]rhs.entries[5]+entries[10]*rhs.entries[6],
169	0.0f,
170	entries[0]rhs.entries[8]+entries[4]rhs.entries[9]+entries[8]*rhs.entries[10],
171	entries[1]rhs.entries[8]+entries[5]rhs.entries[9]+entries[9]*rhs.entries[10],
172	entries[2]rhs.entries[8]+entries[6]rhs.entries[9]+entries[10]*rhs.entries[10],
173	0.0f,
174	entries[0]rhs.entries[12]+entries[4]rhs.entries[13]+entries[8]*rhs.entries[14]+entries[12],
175	entries[1]rhs.entries[12]+entries[5]rhs.entries[13]+entries[9]*rhs.entries[14]+entries[13],
176	entries[2]rhs.entries[12]+entries[6]rhs.entries[13]+entries[10]*rhs.entries[14]+entries[14],
177	1.0f);
178	}
179
180	//Optimise for when bottom row of 1st matrix is (0, 0, 0, 1)
181	if( entries[3]==0.0f && entries[7]==0.0f && entries[11]==0.0f && entries[15]==1.0f)
182	{
183	return MATRIX4X4( entries[0]rhs.entries[0]+entries[4]rhs.entries[1]+entries[8]rhs.entries[2]+entries[12]rhs.entries[3],
184	entries[1]rhs.entries[0]+entries[5]rhs.entries[1]+entries[9]rhs.entries[2]+entries[13]rhs.entries[3],
185	entries[2]rhs.entries[0]+entries[6]rhs.entries[1]+entries[10]rhs.entries[2]+entries[14]rhs.entries[3],
186	rhs.entries[3],
187	entries[0]rhs.entries[4]+entries[4]rhs.entries[5]+entries[8]rhs.entries[6]+entries[12]rhs.entries[7],
188	entries[1]rhs.entries[4]+entries[5]rhs.entries[5]+entries[9]rhs.entries[6]+entries[13]rhs.entries[7],
189	entries[2]rhs.entries[4]+entries[6]rhs.entries[5]+entries[10]rhs.entries[6]+entries[14]rhs.entries[7],
190	rhs.entries[7],
191	entries[0]rhs.entries[8]+entries[4]rhs.entries[9]+entries[8]rhs.entries[10]+entries[12]rhs.entries[11],
192	entries[1]rhs.entries[8]+entries[5]rhs.entries[9]+entries[9]rhs.entries[10]+entries[13]rhs.entries[11],
193	entries[2]rhs.entries[8]+entries[6]rhs.entries[9]+entries[10]rhs.entries[10]+entries[14]rhs.entries[11],
194	rhs.entries[11],
195	entries[0]rhs.entries[12]+entries[4]rhs.entries[13]+entries[8]rhs.entries[14]+entries[12]rhs.entries[15],
196	entries[1]rhs.entries[12]+entries[5]rhs.entries[13]+entries[9]rhs.entries[14]+entries[13]rhs.entries[15],
197	entries[2]rhs.entries[12]+entries[6]rhs.entries[13]+entries[10]rhs.entries[14]+entries[14]rhs.entries[15],
198	rhs.entries[15]);
199	}
200
201	//Optimise for when bottom row of 2nd matrix is (0, 0, 0, 1)
202	if( rhs.entries[3]==0.0f && rhs.entries[7]==0.0f &&
203	rhs.entries[11]==0.0f && rhs.entries[15]==1.0f)
204	{
205	return MATRIX4X4( entries[0]rhs.entries[0]+entries[4]rhs.entries[1]+entries[8]*rhs.entries[2],
206	entries[1]rhs.entries[0]+entries[5]rhs.entries[1]+entries[9]*rhs.entries[2],
207	entries[2]rhs.entries[0]+entries[6]rhs.entries[1]+entries[10]*rhs.entries[2],
208	entries[3]rhs.entries[0]+entries[7]rhs.entries[1]+entries[11]*rhs.entries[2],
209	entries[0]rhs.entries[4]+entries[4]rhs.entries[5]+entries[8]*rhs.entries[6],
210	entries[1]rhs.entries[4]+entries[5]rhs.entries[5]+entries[9]*rhs.entries[6],
211	entries[2]rhs.entries[4]+entries[6]rhs.entries[5]+entries[10]*rhs.entries[6],
212	entries[3]rhs.entries[4]+entries[7]rhs.entries[5]+entries[11]*rhs.entries[6],
213	entries[0]rhs.entries[8]+entries[4]rhs.entries[9]+entries[8]*rhs.entries[10],
214	entries[1]rhs.entries[8]+entries[5]rhs.entries[9]+entries[9]*rhs.entries[10],
215	entries[2]rhs.entries[8]+entries[6]rhs.entries[9]+entries[10]*rhs.entries[10],
216	entries[3]rhs.entries[8]+entries[7]rhs.entries[9]+entries[11]*rhs.entries[10],
217	entries[0]rhs.entries[12]+entries[4]rhs.entries[13]+entries[8]*rhs.entries[14]+entries[12],
218	entries[1]rhs.entries[12]+entries[5]rhs.entries[13]+entries[9]*rhs.entries[14]+entries[13],
219	entries[2]rhs.entries[12]+entries[6]rhs.entries[13]+entries[10]*rhs.entries[14]+entries[14],
220	entries[3]rhs.entries[12]+entries[7]rhs.entries[13]+entries[11]*rhs.entries[14]+entries[15]);
221	}
222
223	return MATRIX4X4( entries[0]rhs.entries[0]+entries[4]rhs.entries[1]+entries[8]rhs.entries[2]+entries[12]rhs.entries[3],
224	entries[1]rhs.entries[0]+entries[5]rhs.entries[1]+entries[9]rhs.entries[2]+entries[13]rhs.entries[3],
225	entries[2]rhs.entries[0]+entries[6]rhs.entries[1]+entries[10]rhs.entries[2]+entries[14]rhs.entries[3],
226	entries[3]rhs.entries[0]+entries[7]rhs.entries[1]+entries[11]rhs.entries[2]+entries[15]rhs.entries[3],
227	entries[0]rhs.entries[4]+entries[4]rhs.entries[5]+entries[8]rhs.entries[6]+entries[12]rhs.entries[7],
228	entries[1]rhs.entries[4]+entries[5]rhs.entries[5]+entries[9]rhs.entries[6]+entries[13]rhs.entries[7],
229	entries[2]rhs.entries[4]+entries[6]rhs.entries[5]+entries[10]rhs.entries[6]+entries[14]rhs.entries[7],
230	entries[3]rhs.entries[4]+entries[7]rhs.entries[5]+entries[11]rhs.entries[6]+entries[15]rhs.entries[7],
231	entries[0]rhs.entries[8]+entries[4]rhs.entries[9]+entries[8]rhs.entries[10]+entries[12]rhs.entries[11],
232	entries[1]rhs.entries[8]+entries[5]rhs.entries[9]+entries[9]rhs.entries[10]+entries[13]rhs.entries[11],
233	entries[2]rhs.entries[8]+entries[6]rhs.entries[9]+entries[10]rhs.entries[10]+entries[14]rhs.entries[11],
234	entries[3]rhs.entries[8]+entries[7]rhs.entries[9]+entries[11]rhs.entries[10]+entries[15]rhs.entries[11],
235	entries[0]rhs.entries[12]+entries[4]rhs.entries[13]+entries[8]rhs.entries[14]+entries[12]rhs.entries[15],
236	entries[1]rhs.entries[12]+entries[5]rhs.entries[13]+entries[9]rhs.entries[14]+entries[13]rhs.entries[15],
237	entries[2]rhs.entries[12]+entries[6]rhs.entries[13]+entries[10]rhs.entries[14]+entries[14]rhs.entries[15],
238	entries[3]rhs.entries[12]+entries[7]rhs.entries[13]+entries[11]rhs.entries[14]+entries[15]rhs.entries[15]);
239	}
240
241	MATRIX4X4 MATRIX4X4::operator*(const float rhs) const
242	{
243	return MATRIX4X4( entries[0]*rhs,
244	entries[1]*rhs,
245	entries[2]*rhs,
246	entries[3]*rhs,
247	entries[4]*rhs,
248	entries[5]*rhs,
249	entries[6]*rhs,
250	entries[7]*rhs,
251	entries[8]*rhs,
252	entries[9]*rhs,
253	entries[10]*rhs,
254	entries[11]*rhs,
255	entries[12]*rhs,
256	entries[13]*rhs,
257	entries[14]*rhs,
258	entries[15]*rhs);
259	}
260
261	MATRIX4X4 MATRIX4X4::operator/(const float rhs) const
262	{
263	if (rhs==0.0f \|\| rhs==1.0f)
264	return (*this);
265
266	float temp=1/rhs;
267
268	return (this)temp;
269	}
270
271	MATRIX4X4 operator*(float scaleFactor, const MATRIX4X4 & rhs)
272	{
273	return rhs*scaleFactor;
274	}
275
276	bool MATRIX4X4::operator==(const MATRIX4X4 & rhs) const
277	{
278	for(int i=0; i<16; i++)
279	{
280	if(entries[i]!=rhs.entries[i])
281	return false;
282	}
283	return true;
284	}
285
286	bool MATRIX4X4::operator!=(const MATRIX4X4 & rhs) const
287	{
288	return !((*this)==rhs);
289	}
290
291	void MATRIX4X4::operator+=(const MATRIX4X4 & rhs)
292	{
293	(this)=(this)+rhs;
294	}
295
296	void MATRIX4X4::operator-=(const MATRIX4X4 & rhs)
297	{
298	(this)=(this)-rhs;
299	}
300
301	void MATRIX4X4::operator*=(const MATRIX4X4 & rhs)
302	{
303	(this)=(this)*rhs;
304	}
305
306	void MATRIX4X4::operator*=(const float rhs)
307	{
308	(this)=(this)*rhs;
309	}
310
311	void MATRIX4X4::operator/=(const float rhs)
312	{
313	(this)=(this)/rhs;
314	}
315
316	MATRIX4X4 MATRIX4X4::operator-(void) const
317	{
318	MATRIX4X4 result(*this);
319
320	for(int i=0; i<16; i++)
321	result.entries[i]=-result.entries[i];
322
323	return result;
324	}
325
326	VECTOR4D MATRIX4X4::operator*(const VECTOR4D rhs) const
327	{
328	//Optimise for matrices in which bottom row is (0, 0, 0, 1)
329	if(entries[3]==0.0f && entries[7]==0.0f && entries[11]==0.0f && entries[15]==1.0f)
330	{
331	return VECTOR4D(entries[0]*rhs.x
332	+ entries[4]*rhs.y
333	+ entries[8]*rhs.z
334	+ entries[12]*rhs.w,
335
336	entries[1]*rhs.x
337	+ entries[5]*rhs.y
338	+ entries[9]*rhs.z
339	+ entries[13]*rhs.w,
340
341	entries[2]*rhs.x
342	+ entries[6]*rhs.y
343	+ entries[10]*rhs.z
344	+ entries[14]*rhs.w,
345
346	rhs.w);
347	}
348
349	return VECTOR4D( entries[0]*rhs.x
350	+ entries[4]*rhs.y
351	+ entries[8]*rhs.z
352	+ entries[12]*rhs.w,
353
354	entries[1]*rhs.x
355	+ entries[5]*rhs.y
356	+ entries[9]*rhs.z
357	+ entries[13]*rhs.w,
358
359	entries[2]*rhs.x
360	+ entries[6]*rhs.y
361	+ entries[10]*rhs.z
362	+ entries[14]*rhs.w,
363
364	entries[3]*rhs.x
365	+ entries[7]*rhs.y
366	+ entries[11]*rhs.z
367	+ entries[15]*rhs.w);
368	}
369
370	VECTOR3D MATRIX4X4::GetRotatedVector3D(const VECTOR3D & rhs) const
371	{
372	return VECTOR3D(entries[0]rhs.x + entries[4]rhs.y + entries[8]*rhs.z,
373	entries[1]rhs.x + entries[5]rhs.y + entries[9]*rhs.z,
374	entries[2]rhs.x + entries[6]rhs.y + entries[10]*rhs.z);
375	}
376
377	VECTOR3D MATRIX4X4::GetInverseRotatedVector3D(const VECTOR3D & rhs) const
378	{
379	//rotate by transpose:
380	return VECTOR3D(entries[0]rhs.x + entries[1]rhs.y + entries[2]*rhs.z,
381	entries[4]rhs.x + entries[5]rhs.y + entries[6]*rhs.z,
382	entries[8]rhs.x + entries[9]rhs.y + entries[10]*rhs.z);
383	}
384
385	VECTOR3D MATRIX4X4::GetTranslatedVector3D(const VECTOR3D & rhs) const
386	{
387	return VECTOR3D(rhs.x+entries[12], rhs.y+entries[13], rhs.z+entries[14]);
388	}
389
390	VECTOR3D MATRIX4X4::GetInverseTranslatedVector3D(const VECTOR3D & rhs) const
391	{
392	return VECTOR3D(rhs.x-entries[12], rhs.y-entries[13], rhs.z-entries[14]);
393	}
394
395	void MATRIX4X4::Invert(void)
396	{
397	*this=GetInverse();
398	}
399
400	MATRIX4X4 MATRIX4X4::GetInverse(void) const
401	{
402	MATRIX4X4 result=GetInverseTranspose();
403
404	result.Transpose();
405
406	return result;
407	}
408
409
410	void MATRIX4X4::Transpose(void)
411	{
412	*this=GetTranspose();
413	}
414
415	MATRIX4X4 MATRIX4X4::GetTranspose(void) const
416	{
417	return MATRIX4X4( entries[ 0], entries[ 4], entries[ 8], entries[12],
418	entries[ 1], entries[ 5], entries[ 9], entries[13],
419	entries[ 2], entries[ 6], entries[10], entries[14],
420	entries[ 3], entries[ 7], entries[11], entries[15]);
421	}
422
423	void MATRIX4X4::InvertTranspose(void)
424	{
425	*this=GetInverseTranspose();
426	}
427
428	MATRIX4X4 MATRIX4X4::GetInverseTranspose(void) const
429	{
430	MATRIX4X4 result;
431
432	float tmp[12]; //temporary pair storage
433	float det; //determinant
434
435	//calculate pairs for first 8 elements (cofactors)
436	tmp[0] = entries[10] * entries[15];
437	tmp[1] = entries[11] * entries[14];
438	tmp[2] = entries[9] * entries[15];
439	tmp[3] = entries[11] * entries[13];
440	tmp[4] = entries[9] * entries[14];
441	tmp[5] = entries[10] * entries[13];
442	tmp[6] = entries[8] * entries[15];
443	tmp[7] = entries[11] * entries[12];
444	tmp[8] = entries[8] * entries[14];
445	tmp[9] = entries[10] * entries[12];
446	tmp[10] = entries[8] * entries[13];
447	tmp[11] = entries[9] * entries[12];
448
449	//calculate first 8 elements (cofactors)
450	result.SetEntry(0, tmp[0]entries[5] + tmp[3]entries[6] + tmp[4]*entries[7]
451	- tmp[1]entries[5] - tmp[2]entries[6] - tmp[5]*entries[7]);
452
453	result.SetEntry(1, tmp[1]entries[4] + tmp[6]entries[6] + tmp[9]*entries[7]
454	- tmp[0]entries[4] - tmp[7]entries[6] - tmp[8]*entries[7]);
455
456	result.SetEntry(2, tmp[2]entries[4] + tmp[7]entries[5] + tmp[10]*entries[7]
457	- tmp[3]entries[4] - tmp[6]entries[5] - tmp[11]*entries[7]);
458
459	result.SetEntry(3, tmp[5]entries[4] + tmp[8]entries[5] + tmp[11]*entries[6]
460	- tmp[4]entries[4] - tmp[9]entries[5] - tmp[10]*entries[6]);
461
462	result.SetEntry(4, tmp[1]entries[1] + tmp[2]entries[2] + tmp[5]*entries[3]
463	- tmp[0]entries[1] - tmp[3]entries[2] - tmp[4]*entries[3]);
464
465	result.SetEntry(5, tmp[0]entries[0] + tmp[7]entries[2] + tmp[8]*entries[3]
466	- tmp[1]entries[0] - tmp[6]entries[2] - tmp[9]*entries[3]);
467
468	result.SetEntry(6, tmp[3]entries[0] + tmp[6]entries[1] + tmp[11]*entries[3]
469	- tmp[2]entries[0] - tmp[7]entries[1] - tmp[10]*entries[3]);
470
471	result.SetEntry(7, tmp[4]entries[0] + tmp[9]entries[1] + tmp[10]*entries[2]
472	- tmp[5]entries[0] - tmp[8]entries[1] - tmp[11]*entries[2]);
473
474	//calculate pairs for second 8 elements (cofactors)
475	tmp[0] = entries[2]*entries[7];
476	tmp[1] = entries[3]*entries[6];
477	tmp[2] = entries[1]*entries[7];
478	tmp[3] = entries[3]*entries[5];
479	tmp[4] = entries[1]*entries[6];
480	tmp[5] = entries[2]*entries[5];
481	tmp[6] = entries[0]*entries[7];
482	tmp[7] = entries[3]*entries[4];
483	tmp[8] = entries[0]*entries[6];
484	tmp[9] = entries[2]*entries[4];
485	tmp[10] = entries[0]*entries[5];
486	tmp[11] = entries[1]*entries[4];
487
488	//calculate second 8 elements (cofactors)
489	result.SetEntry(8, tmp[0]entries[13] + tmp[3]entries[14] + tmp[4]*entries[15]
490	- tmp[1]entries[13] - tmp[2]entries[14] - tmp[5]*entries[15]);
491
492	result.SetEntry(9, tmp[1]entries[12] + tmp[6]entries[14] + tmp[9]*entries[15]
493	- tmp[0]entries[12] - tmp[7]entries[14] - tmp[8]*entries[15]);
494
495	result.SetEntry(10, tmp[2]entries[12] + tmp[7]entries[13] + tmp[10]*entries[15]
496	- tmp[3]entries[12] - tmp[6]entries[13] - tmp[11]*entries[15]);
497
498	result.SetEntry(11, tmp[5]entries[12] + tmp[8]entries[13] + tmp[11]*entries[14]
499	- tmp[4]entries[12] - tmp[9]entries[13] - tmp[10]*entries[14]);
500
501	result.SetEntry(12, tmp[2]entries[10] + tmp[5]entries[11] + tmp[1]*entries[9]
502	- tmp[4]entries[11] - tmp[0]entries[9] - tmp[3]*entries[10]);
503
504	result.SetEntry(13, tmp[8]entries[11] + tmp[0]entries[8] + tmp[7]*entries[10]
505	- tmp[6]entries[10] - tmp[9]entries[11] - tmp[1]*entries[8]);
506
507	result.SetEntry(14, tmp[6]entries[9] + tmp[11]entries[11] + tmp[3]*entries[8]
508	- tmp[10]entries[11] - tmp[2]entries[8] - tmp[7]*entries[9]);
509
510	result.SetEntry(15, tmp[10]entries[10] + tmp[4]entries[8] + tmp[9]*entries[9]
511	- tmp[8]entries[9] - tmp[11]entries[10] - tmp[5]*entries[8]);
512
513	// calculate determinant
514	det = entries[0]*result.GetEntry(0)
515	+entries[1]*result.GetEntry(1)
516	+entries[2]*result.GetEntry(2)
517	+entries[3]*result.GetEntry(3);
518
519	if(det==0.0f)
520	{
521	MATRIX4X4 id;
522	return id;
523	}
524
525	result=result/det;
526
527	return result;
528	}
529
530	//Invert if only composed of rotations & translations
531	void MATRIX4X4::AffineInvert(void)
532	{
533	(*this)=GetAffineInverse();
534	}
535
536	MATRIX4X4 MATRIX4X4::GetAffineInverse(void) const
537	{
538	//return the transpose of the rotation part
539	//and the negative of the inverse rotated translation part
540	return MATRIX4X4( entries[0],
541	entries[4],
542	entries[8],
543	0.0f,
544	entries[1],
545	entries[5],
546	entries[9],
547	0.0f,
548	entries[2],
549	entries[6],
550	entries[10],
551	0.0f,
552	-(entries[0]entries[12]+entries[1]entries[13]+entries[2]*entries[14]),
553	-(entries[4]entries[12]+entries[5]entries[13]+entries[6]*entries[14]),
554	-(entries[8]entries[12]+entries[9]entries[13]+entries[10]*entries[14]),
555	1.0f);
556	}
557
558	void MATRIX4X4::AffineInvertTranspose(void)
559	{
560	(*this)=GetAffineInverseTranspose();
561	}
562
563	MATRIX4X4 MATRIX4X4::GetAffineInverseTranspose(void) const
564	{
565	//return the transpose of the rotation part
566	//and the negative of the inverse rotated translation part
567	//transposed
568	return MATRIX4X4( entries[0],
569	entries[1],
570	entries[2],
571	-(entries[0]entries[12]+entries[1]entries[13]+entries[2]*entries[14]),
572	entries[4],
573	entries[5],
574	entries[6],
575	-(entries[4]entries[12]+entries[5]entries[13]+entries[6]*entries[14]),
576	entries[8],
577	entries[9],
578	entries[10],
579	-(entries[8]entries[12]+entries[9]entries[13]+entries[10]*entries[14]),
580	0.0f, 0.0f, 0.0f, 1.0f);
581	}
582
583	void MATRIX4X4::SetTranslation(const VECTOR3D & translation)
584	{
585	LoadIdentity();
586
587	SetTranslationPart(translation);
588	}
589
590	void MATRIX4X4::SetScale(const VECTOR3D & scaleFactor)
591	{
592	LoadIdentity();
593
594	entries[0]=scaleFactor.x;
595	entries[5]=scaleFactor.y;
596	entries[10]=scaleFactor.z;
597	}
598
599	void MATRIX4X4::SetUniformScale(const float scaleFactor)
600	{
601	LoadIdentity();
602
603	entries[0]=entries[5]=entries[10]=scaleFactor;
604	}
605
606	void MATRIX4X4::SetRotationAxis(const double angle, const VECTOR3D & axis)
607	{
608	VECTOR3D u=axis.GetNormalized();
609
610	float sinAngle=(float)sin(M_PI*angle/180);
611	float cosAngle=(float)cos(M_PI*angle/180);
612	float oneMinusCosAngle=1.0f-cosAngle;
613
614	LoadIdentity();
615
616	entries[0]=(u.x)(u.x) + cosAngle(1-(u.x)*(u.x));
617	entries[4]=(u.x)(u.y)(oneMinusCosAngle) - sinAngle*u.z;
618	entries[8]=(u.x)(u.z)(oneMinusCosAngle) + sinAngle*u.y;
619
620	entries[1]=(u.x)(u.y)(oneMinusCosAngle) + sinAngle*u.z;
621	entries[5]=(u.y)(u.y) + cosAngle(1-(u.y)*(u.y));
622	entries[9]=(u.y)(u.z)(oneMinusCosAngle) - sinAngle*u.x;
623
624	entries[2]=(u.x)(u.z)(oneMinusCosAngle) - sinAngle*u.y;
625	entries[6]=(u.y)(u.z)(oneMinusCosAngle) + sinAngle*u.x;
626	entries[10]=(u.z)(u.z) + cosAngle(1-(u.z)*(u.z));
627	}
628
629	void MATRIX4X4::SetRotationX(const double angle)
630	{
631	LoadIdentity();
632
633	entries[5]=(float)cos(M_PI*angle/180);
634	entries[6]=(float)sin(M_PI*angle/180);
635
636	entries[9]=-entries[6];
637	entries[10]=entries[5];
638	}
639
640	void MATRIX4X4::SetRotationY(const double angle)
641	{
642	LoadIdentity();
643
644	entries[0]=(float)cos(M_PI*angle/180);
645	entries[2]=-(float)sin(M_PI*angle/180);
646
647	entries[8]=-entries[2];
648	entries[10]=entries[0];
649	}
650
651	void MATRIX4X4::SetRotationZ(const double angle)
652	{
653	LoadIdentity();
654
655	entries[0]=(float)cos(M_PI*angle/180);
656	entries[1]=(float)sin(M_PI*angle/180);
657
658	entries[4]=-entries[1];
659	entries[5]=entries[0];
660	}
661
662	void MATRIX4X4::SetRotationEuler(const double angleX, const double angleY, const double angleZ)
663	{
664	LoadIdentity();
665
666	SetRotationPartEuler(angleX, angleY, angleZ);
667	}
668
669	void MATRIX4X4::SetPerspective( float left, float right, float bottom,
670	float top, float n, float f)
671	{
672	float nudge=0.999f; //prevent artifacts with infinite far plane
673
674	LoadZero();
675
676	//check for division by 0
677	if(left==right \|\| top==bottom \|\| n==f)
678	return;
679
680	entries[0]=(2*n)/(right-left);
681
682	entries[5]=(2*n)/(top-bottom);
683
684	entries[8]=(right+left)/(right-left);
685	entries[9]=(top+bottom)/(top-bottom);
686
687	if(f!=-1)
688	{
689	entries[10]=-(f+n)/(f-n);
690	}
691	else //if f==-1, use an infinite far plane
692	{
693	entries[10]=-nudge;
694	}
695
696	entries[11]=-1;
697
698	if(f!=-1)
699	{
700	entries[14]=-(2fn)/(f-n);
701	}
702	else //if f==-1, use an infinite far plane
703	{
704	entries[14]=-2nnudge;
705	}
706	}
707
708	void MATRIX4X4::SetPerspective(float fovy, float aspect, float n, float f)
709	{
710	float left, right, top, bottom;
711
712	//convert fov from degrees to radians
713	fovy*=(float)M_PI/180;
714
715	top=n*tanf(fovy/2.0f);
716	bottom=-top;
717
718	left=aspect*bottom;
719	right=aspect*top;
720
721	SetPerspective(left, right, bottom, top, n, f);
722	}
723
724	void MATRIX4X4::SetOrtho( float left, float right, float bottom,
725	float top, float n, float f)
726	{
727	LoadIdentity();
728
729	entries[0]=2.0f/(right-left);
730
731	entries[5]=2.0f/(top-bottom);
732
733	entries[10]=-2.0f/(f-n);
734
735	entries[12]=-(right+left)/(right-left);
736	entries[13]=-(top+bottom)/(top-bottom);
737	entries[14]=-(f+n)/(f-n);
738	}
739
740	void MATRIX4X4::SetTranslationPart(const VECTOR3D & translation)
741	{
742	entries[12]=translation.x;
743	entries[13]=translation.y;
744	entries[14]=translation.z;
745	}
746
747	void MATRIX4X4::SetRotationPartEuler(const double angleX, const double angleY, const double angleZ)
748	{
749	double cr = cos( M_PI*angleX/180 );
750	double sr = sin( M_PI*angleX/180 );
751	double cp = cos( M_PI*angleY/180 );
752	double sp = sin( M_PI*angleY/180 );
753	double cy = cos( M_PI*angleZ/180 );
754	double sy = sin( M_PI*angleZ/180 );
755
756	entries[0] = ( float )( cp*cy );
757	entries[1] = ( float )( cp*sy );
758	entries[2] = ( float )( -sp );
759
760	double srsp = sr*sp;
761	double crsp = cr*sp;
762
763	entries[4] = ( float )( srspcy-crsy );
764	entries[5] = ( float )( srspsy+crcy );
765	entries[6] = ( float )( sr*cp );
766
767	entries[8] = ( float )( crspcy+srsy );
768	entries[9] = ( float )( crspsy-srcy );
769	entries[10] = ( float )( cr*cp );
770	}

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source: GTP/trunk/Lib/Illum/GPUObscurancesGT/src/MATRIX4X4.cpp @ 930

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