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btMatrix3x3.h @ 8351

Last change on this file since 8351 was 8351, checked in by rgrieder, 13 years ago

Merged kicklib2 branch back to trunk (includes former branches ois_update, mac_osx and kicklib).

Notes for updating

Linux:
You don't need an extra package for CEGUILua and Tolua, it's already shipped with CEGUI.
However you do need to make sure that the OgreRenderer is installed too with CEGUI 0.7 (may be a separate package).
Also, Orxonox now recognises if you install the CgProgramManager (a separate package available on newer Ubuntu on Debian systems).

Windows:
Download the new dependency packages versioned 6.0 and use these. If you have problems with that or if you don't like the in game console problem mentioned below, you can download the new 4.3 version of the packages (only available for Visual Studio 2005/2008).

Key new features:

*Support for Mac OS X*
Visual Studio 2010 support
Bullet library update to 2.77
OIS library update to 1.3
Support for CEGUI 0.7 —> Support for Arch Linux and even SuSE
Improved install target
Compiles now with GCC 4.6
Ogre Cg Shader plugin activated for Linux if available
And of course lots of bug fixes

There are also some regressions:

No support for CEGUI 0.5, Ogre 1.4 and boost 1.35 - 1.39 any more
In game console is not working in main menu for CEGUI 0.7
Tolua (just the C lib, not the application) and CEGUILua libraries are no longer in our repository. —> You will need to get these as well when compiling Orxonox
And of course lots of new bugs we don't yet know about

Property svn:eol-style set to native

File size: 20.6 KB

Line
1	/*
2	Copyright (c) 2003-2006 Gino van den Bergen / Erwin Coumans http://continuousphysics.com/Bullet/
3
4	This software is provided 'as-is', without any express or implied warranty.
5	In no event will the authors be held liable for any damages arising from the use of this software.
6	Permission is granted to anyone to use this software for any purpose,
7	including commercial applications, and to alter it and redistribute it freely,
8	subject to the following restrictions:
9
10	1. The origin of this software must not be misrepresented; you must not claim that you wrote the original software. If you use this software in a product, an acknowledgment in the product documentation would be appreciated but is not required.
11	2. Altered source versions must be plainly marked as such, and must not be misrepresented as being the original software.
12	3. This notice may not be removed or altered from any source distribution.
13	*/
14
15
16	#ifndef BT_MATRIX3x3_H
17	#define BT_MATRIX3x3_H
18
19	#include "btVector3.h"
20	#include "btQuaternion.h"
21
22	#ifdef BT_USE_DOUBLE_PRECISION
23	#define btMatrix3x3Data btMatrix3x3DoubleData
24	#else
25	#define btMatrix3x3Data btMatrix3x3FloatData
26	#endif //BT_USE_DOUBLE_PRECISION
27
28
29	/**@brief The btMatrix3x3 class implements a 3x3 rotation matrix, to perform linear algebra in combination with btQuaternion, btTransform and btVector3.
30	* Make sure to only include a pure orthogonal matrix without scaling. */
31	class btMatrix3x3 {
32
33	///Data storage for the matrix, each vector is a row of the matrix
34	btVector3 m_el[3];
35
36	public:
37	/** @brief No initializaion constructor */
38	btMatrix3x3 () {}
39
40	// explicit btMatrix3x3(const btScalar *m) { setFromOpenGLSubMatrix(m); }
41
42	/*@brief Constructor from Quaternion /
43	explicit btMatrix3x3(const btQuaternion& q) { setRotation(q); }
44	/*
45	template <typename btScalar>
46	Matrix3x3(const btScalar& yaw, const btScalar& pitch, const btScalar& roll)
47	{
48	setEulerYPR(yaw, pitch, roll);
49	}
50	*/
51	/** @brief Constructor with row major formatting */
52	btMatrix3x3(const btScalar& xx, const btScalar& xy, const btScalar& xz,
53	const btScalar& yx, const btScalar& yy, const btScalar& yz,
54	const btScalar& zx, const btScalar& zy, const btScalar& zz)
55	{
56	setValue(xx, xy, xz,
57	yx, yy, yz,
58	zx, zy, zz);
59	}
60	/** @brief Copy constructor */
61	SIMD_FORCE_INLINE btMatrix3x3 (const btMatrix3x3& other)
62	{
63	m_el[0] = other.m_el[0];
64	m_el[1] = other.m_el[1];
65	m_el[2] = other.m_el[2];
66	}
67	/** @brief Assignment Operator */
68	SIMD_FORCE_INLINE btMatrix3x3& operator=(const btMatrix3x3& other)
69	{
70	m_el[0] = other.m_el[0];
71	m_el[1] = other.m_el[1];
72	m_el[2] = other.m_el[2];
73	return *this;
74	}
75
76	/** @brief Get a column of the matrix as a vector
77	* @param i Column number 0 indexed */
78	SIMD_FORCE_INLINE btVector3 getColumn(int i) const
79	{
80	return btVector3(m_el[0][i],m_el[1][i],m_el[2][i]);
81	}
82
83
84	/** @brief Get a row of the matrix as a vector
85	* @param i Row number 0 indexed */
86	SIMD_FORCE_INLINE const btVector3& getRow(int i) const
87	{
88	btFullAssert(0 <= i && i < 3);
89	return m_el[i];
90	}
91
92	/** @brief Get a mutable reference to a row of the matrix as a vector
93	* @param i Row number 0 indexed */
94	SIMD_FORCE_INLINE btVector3& operator[](int i)
95	{
96	btFullAssert(0 <= i && i < 3);
97	return m_el[i];
98	}
99
100	/** @brief Get a const reference to a row of the matrix as a vector
101	* @param i Row number 0 indexed */
102	SIMD_FORCE_INLINE const btVector3& operator[](int i) const
103	{
104	btFullAssert(0 <= i && i < 3);
105	return m_el[i];
106	}
107
108	/** @brief Multiply by the target matrix on the right
109	* @param m Rotation matrix to be applied
110	* Equivilant to this = this * m */
111	btMatrix3x3& operator*=(const btMatrix3x3& m);
112
113	/** @brief Set from a carray of btScalars
114	* @param m A pointer to the beginning of an array of 9 btScalars */
115	void setFromOpenGLSubMatrix(const btScalar *m)
116	{
117	m_el[0].setValue(m[0],m[4],m[8]);
118	m_el[1].setValue(m[1],m[5],m[9]);
119	m_el[2].setValue(m[2],m[6],m[10]);
120
121	}
122	/** @brief Set the values of the matrix explicitly (row major)
123	* @param xx Top left
124	* @param xy Top Middle
125	* @param xz Top Right
126	* @param yx Middle Left
127	* @param yy Middle Middle
128	* @param yz Middle Right
129	* @param zx Bottom Left
130	* @param zy Bottom Middle
131	* @param zz Bottom Right*/
132	void setValue(const btScalar& xx, const btScalar& xy, const btScalar& xz,
133	const btScalar& yx, const btScalar& yy, const btScalar& yz,
134	const btScalar& zx, const btScalar& zy, const btScalar& zz)
135	{
136	m_el[0].setValue(xx,xy,xz);
137	m_el[1].setValue(yx,yy,yz);
138	m_el[2].setValue(zx,zy,zz);
139	}
140
141	/** @brief Set the matrix from a quaternion
142	* @param q The Quaternion to match */
143	void setRotation(const btQuaternion& q)
144	{
145	btScalar d = q.length2();
146	btFullAssert(d != btScalar(0.0));
147	btScalar s = btScalar(2.0) / d;
148	btScalar xs = q.x() * s, ys = q.y() * s, zs = q.z() * s;
149	btScalar wx = q.w() * xs, wy = q.w() * ys, wz = q.w() * zs;
150	btScalar xx = q.x() * xs, xy = q.x() * ys, xz = q.x() * zs;
151	btScalar yy = q.y() * ys, yz = q.y() * zs, zz = q.z() * zs;
152	setValue(btScalar(1.0) - (yy + zz), xy - wz, xz + wy,
153	xy + wz, btScalar(1.0) - (xx + zz), yz - wx,
154	xz - wy, yz + wx, btScalar(1.0) - (xx + yy));
155	}
156
157
158	/** @brief Set the matrix from euler angles using YPR around YXZ respectively
159	* @param yaw Yaw about Y axis
160	* @param pitch Pitch about X axis
161	* @param roll Roll about Z axis
162	*/
163	void setEulerYPR(const btScalar& yaw, const btScalar& pitch, const btScalar& roll)
164	{
165	setEulerZYX(roll, pitch, yaw);
166	}
167
168	/** @brief Set the matrix from euler angles YPR around ZYX axes
169	* @param eulerX Roll about X axis
170	* @param eulerY Pitch around Y axis
171	* @param eulerZ Yaw aboud Z axis
172	*
173	* These angles are used to produce a rotation matrix. The euler
174	* angles are applied in ZYX order. I.e a vector is first rotated
175	* about X then Y and then Z
176	**/
177	void setEulerZYX(btScalar eulerX,btScalar eulerY,btScalar eulerZ) {
178	///@todo proposed to reverse this since it's labeled zyx but takes arguments xyz and it will match all other parts of the code
179	btScalar ci ( btCos(eulerX));
180	btScalar cj ( btCos(eulerY));
181	btScalar ch ( btCos(eulerZ));
182	btScalar si ( btSin(eulerX));
183	btScalar sj ( btSin(eulerY));
184	btScalar sh ( btSin(eulerZ));
185	btScalar cc = ci * ch;
186	btScalar cs = ci * sh;
187	btScalar sc = si * ch;
188	btScalar ss = si * sh;
189
190	setValue(cj * ch, sj * sc - cs, sj * cc + ss,
191	cj * sh, sj * ss + cc, sj * cs - sc,
192	-sj, cj * si, cj * ci);
193	}
194
195	/*@brief Set the matrix to the identity /
196	void setIdentity()
197	{
198	setValue(btScalar(1.0), btScalar(0.0), btScalar(0.0),
199	btScalar(0.0), btScalar(1.0), btScalar(0.0),
200	btScalar(0.0), btScalar(0.0), btScalar(1.0));
201	}
202
203	static const btMatrix3x3& getIdentity()
204	{
205	static const btMatrix3x3 identityMatrix(btScalar(1.0), btScalar(0.0), btScalar(0.0),
206	btScalar(0.0), btScalar(1.0), btScalar(0.0),
207	btScalar(0.0), btScalar(0.0), btScalar(1.0));
208	return identityMatrix;
209	}
210
211	/**@brief Fill the values of the matrix into a 9 element array
212	* @param m The array to be filled */
213	void getOpenGLSubMatrix(btScalar *m) const
214	{
215	m[0] = btScalar(m_el[0].x());
216	m[1] = btScalar(m_el[1].x());
217	m[2] = btScalar(m_el[2].x());
218	m[3] = btScalar(0.0);
219	m[4] = btScalar(m_el[0].y());
220	m[5] = btScalar(m_el[1].y());
221	m[6] = btScalar(m_el[2].y());
222	m[7] = btScalar(0.0);
223	m[8] = btScalar(m_el[0].z());
224	m[9] = btScalar(m_el[1].z());
225	m[10] = btScalar(m_el[2].z());
226	m[11] = btScalar(0.0);
227	}
228
229	/**@brief Get the matrix represented as a quaternion
230	* @param q The quaternion which will be set */
231	void getRotation(btQuaternion& q) const
232	{
233	btScalar trace = m_el[0].x() + m_el[1].y() + m_el[2].z();
234	btScalar temp[4];
235
236	if (trace > btScalar(0.0))
237	{
238	btScalar s = btSqrt(trace + btScalar(1.0));
239	temp[3]=(s * btScalar(0.5));
240	s = btScalar(0.5) / s;
241
242	temp[0]=((m_el[2].y() - m_el[1].z()) * s);
243	temp[1]=((m_el[0].z() - m_el[2].x()) * s);
244	temp[2]=((m_el[1].x() - m_el[0].y()) * s);
245	}
246	else
247	{
248	int i = m_el[0].x() < m_el[1].y() ?
249	(m_el[1].y() < m_el[2].z() ? 2 : 1) :
250	(m_el[0].x() < m_el[2].z() ? 2 : 0);
251	int j = (i + 1) % 3;
252	int k = (i + 2) % 3;
253
254	btScalar s = btSqrt(m_el[i][i] - m_el[j][j] - m_el[k][k] + btScalar(1.0));
255	temp[i] = s * btScalar(0.5);
256	s = btScalar(0.5) / s;
257
258	temp[3] = (m_el[k][j] - m_el[j][k]) * s;
259	temp[j] = (m_el[j][i] + m_el[i][j]) * s;
260	temp[k] = (m_el[k][i] + m_el[i][k]) * s;
261	}
262	q.setValue(temp[0],temp[1],temp[2],temp[3]);
263	}
264
265	/**@brief Get the matrix represented as euler angles around YXZ, roundtrip with setEulerYPR
266	* @param yaw Yaw around Y axis
267	* @param pitch Pitch around X axis
268	* @param roll around Z axis */
269	void getEulerYPR(btScalar& yaw, btScalar& pitch, btScalar& roll) const
270	{
271
272	// first use the normal calculus
273	yaw = btScalar(btAtan2(m_el[1].x(), m_el[0].x()));
274	pitch = btScalar(btAsin(-m_el[2].x()));
275	roll = btScalar(btAtan2(m_el[2].y(), m_el[2].z()));
276
277	// on pitch = +/-HalfPI
278	if (btFabs(pitch)==SIMD_HALF_PI)
279	{
280	if (yaw>0)
281	yaw-=SIMD_PI;
282	else
283	yaw+=SIMD_PI;
284
285	if (roll>0)
286	roll-=SIMD_PI;
287	else
288	roll+=SIMD_PI;
289	}
290	};
291
292
293	/**@brief Get the matrix represented as euler angles around ZYX
294	* @param yaw Yaw around X axis
295	* @param pitch Pitch around Y axis
296	* @param roll around X axis
297	* @param solution_number Which solution of two possible solutions ( 1 or 2) are possible values*/
298	void getEulerZYX(btScalar& yaw, btScalar& pitch, btScalar& roll, unsigned int solution_number = 1) const
299	{
300	struct Euler
301	{
302	btScalar yaw;
303	btScalar pitch;
304	btScalar roll;
305	};
306
307	Euler euler_out;
308	Euler euler_out2; //second solution
309	//get the pointer to the raw data
310
311	// Check that pitch is not at a singularity
312	if (btFabs(m_el[2].x()) >= 1)
313	{
314	euler_out.yaw = 0;
315	euler_out2.yaw = 0;
316
317	// From difference of angles formula
318	btScalar delta = btAtan2(m_el[0].x(),m_el[0].z());
319	if (m_el[2].x() > 0) //gimbal locked up
320	{
321	euler_out.pitch = SIMD_PI / btScalar(2.0);
322	euler_out2.pitch = SIMD_PI / btScalar(2.0);
323	euler_out.roll = euler_out.pitch + delta;
324	euler_out2.roll = euler_out.pitch + delta;
325	}
326	else // gimbal locked down
327	{
328	euler_out.pitch = -SIMD_PI / btScalar(2.0);
329	euler_out2.pitch = -SIMD_PI / btScalar(2.0);
330	euler_out.roll = -euler_out.pitch + delta;
331	euler_out2.roll = -euler_out.pitch + delta;
332	}
333	}
334	else
335	{
336	euler_out.pitch = - btAsin(m_el[2].x());
337	euler_out2.pitch = SIMD_PI - euler_out.pitch;
338
339	euler_out.roll = btAtan2(m_el[2].y()/btCos(euler_out.pitch),
340	m_el[2].z()/btCos(euler_out.pitch));
341	euler_out2.roll = btAtan2(m_el[2].y()/btCos(euler_out2.pitch),
342	m_el[2].z()/btCos(euler_out2.pitch));
343
344	euler_out.yaw = btAtan2(m_el[1].x()/btCos(euler_out.pitch),
345	m_el[0].x()/btCos(euler_out.pitch));
346	euler_out2.yaw = btAtan2(m_el[1].x()/btCos(euler_out2.pitch),
347	m_el[0].x()/btCos(euler_out2.pitch));
348	}
349
350	if (solution_number == 1)
351	{
352	yaw = euler_out.yaw;
353	pitch = euler_out.pitch;
354	roll = euler_out.roll;
355	}
356	else
357	{
358	yaw = euler_out2.yaw;
359	pitch = euler_out2.pitch;
360	roll = euler_out2.roll;
361	}
362	}
363
364	/**@brief Create a scaled copy of the matrix
365	* @param s Scaling vector The elements of the vector will scale each column */
366
367	btMatrix3x3 scaled(const btVector3& s) const
368	{
369	return btMatrix3x3(m_el[0].x() * s.x(), m_el[0].y() * s.y(), m_el[0].z() * s.z(),
370	m_el[1].x() * s.x(), m_el[1].y() * s.y(), m_el[1].z() * s.z(),
371	m_el[2].x() * s.x(), m_el[2].y() * s.y(), m_el[2].z() * s.z());
372	}
373
374	/*@brief Return the determinant of the matrix /
375	btScalar determinant() const;
376	/*@brief Return the adjoint of the matrix /
377	btMatrix3x3 adjoint() const;
378	/*@brief Return the matrix with all values non negative /
379	btMatrix3x3 absolute() const;
380	/*@brief Return the transpose of the matrix /
381	btMatrix3x3 transpose() const;
382	/*@brief Return the inverse of the matrix /
383	btMatrix3x3 inverse() const;
384
385	btMatrix3x3 transposeTimes(const btMatrix3x3& m) const;
386	btMatrix3x3 timesTranspose(const btMatrix3x3& m) const;
387
388	SIMD_FORCE_INLINE btScalar tdotx(const btVector3& v) const
389	{
390	return m_el[0].x() * v.x() + m_el[1].x() * v.y() + m_el[2].x() * v.z();
391	}
392	SIMD_FORCE_INLINE btScalar tdoty(const btVector3& v) const
393	{
394	return m_el[0].y() * v.x() + m_el[1].y() * v.y() + m_el[2].y() * v.z();
395	}
396	SIMD_FORCE_INLINE btScalar tdotz(const btVector3& v) const
397	{
398	return m_el[0].z() * v.x() + m_el[1].z() * v.y() + m_el[2].z() * v.z();
399	}
400
401
402	/**@brief diagonalizes this matrix by the Jacobi method.
403	* @param rot stores the rotation from the coordinate system in which the matrix is diagonal to the original
404	* coordinate system, i.e., old_this = rot * new_this * rot^T.
405	* @param threshold See iteration
406	* @param iteration The iteration stops when all off-diagonal elements are less than the threshold multiplied
407	* by the sum of the absolute values of the diagonal, or when maxSteps have been executed.
408	*
409	* Note that this matrix is assumed to be symmetric.
410	*/
411	void diagonalize(btMatrix3x3& rot, btScalar threshold, int maxSteps)
412	{
413	rot.setIdentity();
414	for (int step = maxSteps; step > 0; step--)
415	{
416	// find off-diagonal element [p][q] with largest magnitude
417	int p = 0;
418	int q = 1;
419	int r = 2;
420	btScalar max = btFabs(m_el[0][1]);
421	btScalar v = btFabs(m_el[0][2]);
422	if (v > max)
423	{
424	q = 2;
425	r = 1;
426	max = v;
427	}
428	v = btFabs(m_el[1][2]);
429	if (v > max)
430	{
431	p = 1;
432	q = 2;
433	r = 0;
434	max = v;
435	}
436
437	btScalar t = threshold * (btFabs(m_el[0][0]) + btFabs(m_el[1][1]) + btFabs(m_el[2][2]));
438	if (max <= t)
439	{
440	if (max <= SIMD_EPSILON * t)
441	{
442	return;
443	}
444	step = 1;
445	}
446
447	// compute Jacobi rotation J which leads to a zero for element [p][q]
448	btScalar mpq = m_el[p][q];
449	btScalar theta = (m_el[q][q] - m_el[p][p]) / (2 * mpq);
450	btScalar theta2 = theta * theta;
451	btScalar cos;
452	btScalar sin;
453	if (theta2 * theta2 < btScalar(10 / SIMD_EPSILON))
454	{
455	t = (theta >= 0) ? 1 / (theta + btSqrt(1 + theta2))
456	: 1 / (theta - btSqrt(1 + theta2));
457	cos = 1 / btSqrt(1 + t * t);
458	sin = cos * t;
459	}
460	else
461	{
462	// approximation for large theta-value, i.e., a nearly diagonal matrix
463	t = 1 / (theta * (2 + btScalar(0.5) / theta2));
464	cos = 1 - btScalar(0.5) * t * t;
465	sin = cos * t;
466	}
467
468	// apply rotation to matrix (this = J^T * this * J)
469	m_el[p][q] = m_el[q][p] = 0;
470	m_el[p][p] -= t * mpq;
471	m_el[q][q] += t * mpq;
472	btScalar mrp = m_el[r][p];
473	btScalar mrq = m_el[r][q];
474	m_el[r][p] = m_el[p][r] = cos * mrp - sin * mrq;
475	m_el[r][q] = m_el[q][r] = cos * mrq + sin * mrp;
476
477	// apply rotation to rot (rot = rot * J)
478	for (int i = 0; i < 3; i++)
479	{
480	btVector3& row = rot[i];
481	mrp = row[p];
482	mrq = row[q];
483	row[p] = cos * mrp - sin * mrq;
484	row[q] = cos * mrq + sin * mrp;
485	}
486	}
487	}
488
489
490
491
492	/**@brief Calculate the matrix cofactor
493	* @param r1 The first row to use for calculating the cofactor
494	* @param c1 The first column to use for calculating the cofactor
495	* @param r1 The second row to use for calculating the cofactor
496	* @param c1 The second column to use for calculating the cofactor
497	* See http://en.wikipedia.org/wiki/Cofactor_(linear_algebra) for more details
498	*/
499	btScalar cofac(int r1, int c1, int r2, int c2) const
500	{
501	return m_el[r1][c1] * m_el[r2][c2] - m_el[r1][c2] * m_el[r2][c1];
502	}
503
504	void serialize(struct btMatrix3x3Data& dataOut) const;
505
506	void serializeFloat(struct btMatrix3x3FloatData& dataOut) const;
507
508	void deSerialize(const struct btMatrix3x3Data& dataIn);
509
510	void deSerializeFloat(const struct btMatrix3x3FloatData& dataIn);
511
512	void deSerializeDouble(const struct btMatrix3x3DoubleData& dataIn);
513
514	};
515
516
517	SIMD_FORCE_INLINE btMatrix3x3&
518	btMatrix3x3::operator*=(const btMatrix3x3& m)
519	{
520	setValue(m.tdotx(m_el[0]), m.tdoty(m_el[0]), m.tdotz(m_el[0]),
521	m.tdotx(m_el[1]), m.tdoty(m_el[1]), m.tdotz(m_el[1]),
522	m.tdotx(m_el[2]), m.tdoty(m_el[2]), m.tdotz(m_el[2]));
523	return *this;
524	}
525
526	SIMD_FORCE_INLINE btScalar
527	btMatrix3x3::determinant() const
528	{
529	return btTriple((this)[0], (this)[1], (*this)[2]);
530	}
531
532
533	SIMD_FORCE_INLINE btMatrix3x3
534	btMatrix3x3::absolute() const
535	{
536	return btMatrix3x3(
537	btFabs(m_el[0].x()), btFabs(m_el[0].y()), btFabs(m_el[0].z()),
538	btFabs(m_el[1].x()), btFabs(m_el[1].y()), btFabs(m_el[1].z()),
539	btFabs(m_el[2].x()), btFabs(m_el[2].y()), btFabs(m_el[2].z()));
540	}
541
542	SIMD_FORCE_INLINE btMatrix3x3
543	btMatrix3x3::transpose() const
544	{
545	return btMatrix3x3(m_el[0].x(), m_el[1].x(), m_el[2].x(),
546	m_el[0].y(), m_el[1].y(), m_el[2].y(),
547	m_el[0].z(), m_el[1].z(), m_el[2].z());
548	}
549
550	SIMD_FORCE_INLINE btMatrix3x3
551	btMatrix3x3::adjoint() const
552	{
553	return btMatrix3x3(cofac(1, 1, 2, 2), cofac(0, 2, 2, 1), cofac(0, 1, 1, 2),
554	cofac(1, 2, 2, 0), cofac(0, 0, 2, 2), cofac(0, 2, 1, 0),
555	cofac(1, 0, 2, 1), cofac(0, 1, 2, 0), cofac(0, 0, 1, 1));
556	}
557
558	SIMD_FORCE_INLINE btMatrix3x3
559	btMatrix3x3::inverse() const
560	{
561	btVector3 co(cofac(1, 1, 2, 2), cofac(1, 2, 2, 0), cofac(1, 0, 2, 1));
562	btScalar det = (*this)[0].dot(co);
563	btFullAssert(det != btScalar(0.0));
564	btScalar s = btScalar(1.0) / det;
565	return btMatrix3x3(co.x() * s, cofac(0, 2, 2, 1) * s, cofac(0, 1, 1, 2) * s,
566	co.y() * s, cofac(0, 0, 2, 2) * s, cofac(0, 2, 1, 0) * s,
567	co.z() * s, cofac(0, 1, 2, 0) * s, cofac(0, 0, 1, 1) * s);
568	}
569
570	SIMD_FORCE_INLINE btMatrix3x3
571	btMatrix3x3::transposeTimes(const btMatrix3x3& m) const
572	{
573	return btMatrix3x3(
574	m_el[0].x() * m[0].x() + m_el[1].x() * m[1].x() + m_el[2].x() * m[2].x(),
575	m_el[0].x() * m[0].y() + m_el[1].x() * m[1].y() + m_el[2].x() * m[2].y(),
576	m_el[0].x() * m[0].z() + m_el[1].x() * m[1].z() + m_el[2].x() * m[2].z(),
577	m_el[0].y() * m[0].x() + m_el[1].y() * m[1].x() + m_el[2].y() * m[2].x(),
578	m_el[0].y() * m[0].y() + m_el[1].y() * m[1].y() + m_el[2].y() * m[2].y(),
579	m_el[0].y() * m[0].z() + m_el[1].y() * m[1].z() + m_el[2].y() * m[2].z(),
580	m_el[0].z() * m[0].x() + m_el[1].z() * m[1].x() + m_el[2].z() * m[2].x(),
581	m_el[0].z() * m[0].y() + m_el[1].z() * m[1].y() + m_el[2].z() * m[2].y(),
582	m_el[0].z() * m[0].z() + m_el[1].z() * m[1].z() + m_el[2].z() * m[2].z());
583	}
584
585	SIMD_FORCE_INLINE btMatrix3x3
586	btMatrix3x3::timesTranspose(const btMatrix3x3& m) const
587	{
588	return btMatrix3x3(
589	m_el[0].dot(m[0]), m_el[0].dot(m[1]), m_el[0].dot(m[2]),
590	m_el[1].dot(m[0]), m_el[1].dot(m[1]), m_el[1].dot(m[2]),
591	m_el[2].dot(m[0]), m_el[2].dot(m[1]), m_el[2].dot(m[2]));
592
593	}
594
595	SIMD_FORCE_INLINE btVector3
596	operator*(const btMatrix3x3& m, const btVector3& v)
597	{
598	return btVector3(m[0].dot(v), m[1].dot(v), m[2].dot(v));
599	}
600
601
602	SIMD_FORCE_INLINE btVector3
603	operator*(const btVector3& v, const btMatrix3x3& m)
604	{
605	return btVector3(m.tdotx(v), m.tdoty(v), m.tdotz(v));
606	}
607
608	SIMD_FORCE_INLINE btMatrix3x3
609	operator*(const btMatrix3x3& m1, const btMatrix3x3& m2)
610	{
611	return btMatrix3x3(
612	m2.tdotx( m1[0]), m2.tdoty( m1[0]), m2.tdotz( m1[0]),
613	m2.tdotx( m1[1]), m2.tdoty( m1[1]), m2.tdotz( m1[1]),
614	m2.tdotx( m1[2]), m2.tdoty( m1[2]), m2.tdotz( m1[2]));
615	}
616
617	/*
618	SIMD_FORCE_INLINE btMatrix3x3 btMultTransposeLeft(const btMatrix3x3& m1, const btMatrix3x3& m2) {
619	return btMatrix3x3(
620	m1[0][0] * m2[0][0] + m1[1][0] * m2[1][0] + m1[2][0] * m2[2][0],
621	m1[0][0] * m2[0][1] + m1[1][0] * m2[1][1] + m1[2][0] * m2[2][1],
622	m1[0][0] * m2[0][2] + m1[1][0] * m2[1][2] + m1[2][0] * m2[2][2],
623	m1[0][1] * m2[0][0] + m1[1][1] * m2[1][0] + m1[2][1] * m2[2][0],
624	m1[0][1] * m2[0][1] + m1[1][1] * m2[1][1] + m1[2][1] * m2[2][1],
625	m1[0][1] * m2[0][2] + m1[1][1] * m2[1][2] + m1[2][1] * m2[2][2],
626	m1[0][2] * m2[0][0] + m1[1][2] * m2[1][0] + m1[2][2] * m2[2][0],
627	m1[0][2] * m2[0][1] + m1[1][2] * m2[1][1] + m1[2][2] * m2[2][1],
628	m1[0][2] * m2[0][2] + m1[1][2] * m2[1][2] + m1[2][2] * m2[2][2]);
629	}
630	*/
631
632	/**@brief Equality operator between two matrices
633	* It will test all elements are equal. */
634	SIMD_FORCE_INLINE bool operator==(const btMatrix3x3& m1, const btMatrix3x3& m2)
635	{
636	return ( m1[0][0] == m2[0][0] && m1[1][0] == m2[1][0] && m1[2][0] == m2[2][0] &&
637	m1[0][1] == m2[0][1] && m1[1][1] == m2[1][1] && m1[2][1] == m2[2][1] &&
638	m1[0][2] == m2[0][2] && m1[1][2] == m2[1][2] && m1[2][2] == m2[2][2] );
639	}
640
641	///for serialization
642	struct btMatrix3x3FloatData
643	{
644	btVector3FloatData m_el[3];
645	};
646
647	///for serialization
648	struct btMatrix3x3DoubleData
649	{
650	btVector3DoubleData m_el[3];
651	};
652
653
654
655
656	SIMD_FORCE_INLINE void btMatrix3x3::serialize(struct btMatrix3x3Data& dataOut) const
657	{
658	for (int i=0;i<3;i++)
659	m_el[i].serialize(dataOut.m_el[i]);
660	}
661
662	SIMD_FORCE_INLINE void btMatrix3x3::serializeFloat(struct btMatrix3x3FloatData& dataOut) const
663	{
664	for (int i=0;i<3;i++)
665	m_el[i].serializeFloat(dataOut.m_el[i]);
666	}
667
668
669	SIMD_FORCE_INLINE void btMatrix3x3::deSerialize(const struct btMatrix3x3Data& dataIn)
670	{
671	for (int i=0;i<3;i++)
672	m_el[i].deSerialize(dataIn.m_el[i]);
673	}
674
675	SIMD_FORCE_INLINE void btMatrix3x3::deSerializeFloat(const struct btMatrix3x3FloatData& dataIn)
676	{
677	for (int i=0;i<3;i++)
678	m_el[i].deSerializeFloat(dataIn.m_el[i]);
679	}
680
681	SIMD_FORCE_INLINE void btMatrix3x3::deSerializeDouble(const struct btMatrix3x3DoubleData& dataIn)
682	{
683	for (int i=0;i<3;i++)
684	m_el[i].deSerializeDouble(dataIn.m_el[i]);
685	}
686
687	#endif //BT_MATRIX3x3_H
688

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source: code/trunk/src/external/bullet/LinearMath/btMatrix3x3.h @ 8351

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